This application claims priority to and the benefit of Korean Patent Applications Nos. 2016-0042655 and 2016-0135510, filed on Apr. 7, 2016 and Oct. 19, 2016, respectively, the disclosures of which are incorporated herein by reference in its entirety.
The present invention relates to a fusion polypeptide and a self-assembled nanostructure for inhibiting neovascularization, and more particularly, to a fusion polypeptide for inhibiting neovascularization including a peptide specifically binding to vascular endothelial growth factor (VEGF) receptors; and a hydrophilic elastin-based polypeptide (hydrophilic EBP) linked to the peptide.
In addition, the present invention relates to a fusion polypeptide for inhibiting neovascularization including a peptide specifically binding to VEGF receptors; a hydrophilic EBP linked to the peptide; and a hydrophobic elastin-based polypeptide (hydrophobic EBP) linked to the hydrophilic EBP, and a self-assembled nanostructure thereof.
Peptides, polypeptides and proteins having specific functions, such as cell penetration, cell attachment, binding affinity to target molecules, therapeutic efficacy, and site-specific conjugation, may be fused together to form a multifunctional artificial chimera or fusion protein suitable for smart drug delivery systems.
Such fusion proteins exhibit high specificity, high activity, long half-lives, low accumulation in certain organs, and low side effects when used in vivo. Recently, multifunctional fusion proteins have been prepared at the genetic level with recombinant DNA technology and the following are precisely regulated: (1) sequence and composition of amino acids, (2) fusion order, (3) monodisperse molecular weight, (4) hydrophilicity and hydrophobicity, (5) environmental responsiveness, (6) biocompatibility and biodegradability, (7) toxicity and immunogenicity, (8) pharmacokinetics and pharmacodynamics.
The fusion proteins are expressed in high yield (0.1 to 0.5 g per liter of culture) in prokaryotic or eukaryotic expression systems, and are purified by column chromatography or inverse transition cycling (ITC) for analyzing unique phase transition behaviors induced by stimuli-responsiveness of the fusion proteins. For example, antimicrobial host-defense peptides were genetically fused with polypeptide F4 to overcome limitations of the host-defense peptides, such as low stability, short half-lives and high production cost. Furthermore, tumor-targeting antibodies were prepared in mice using a hybridoma technology, and antigen-binding variable domains of mouse antibodies were combined with human IgG to reduce immunogenicity in patients. A large number of artificial fusion proteins are in preclinical and clinical development, and technologies using multi-functional artificial chimeric or fusion protein-based therapeutics are growing exponentially.
Elastin-based polypeptides (EBPs) are thermal response biopolymers derived from elastomeric domains. Elastin is a major protein component of the extracellular matrix (ECM). EBPs are modified to have thermal sensitivity based on an elastomeric domain and are composed of a pentapeptide repeat unit, Val-Pro-(Gly or Ala)-Xaa-Gly[VP (G or A)XG]. EBPs are thermally responsive polypeptides, and transition temperatures thereof are readily controlled to form nanostructures for drug delivery.
Xaa is a guest residue and may be any amino acid except proline. Depending on a sequence corresponding to the repeat unit, there are two types of EBPs, one is an elastin-based polypeptide with elasticity (EBPE) with a sequence of Val-Pro-Gly-Xaa-Gly and the other is an elastin-based polypeptide with plasticity (EBPP) with a sequence of Val-Pro-Ala-Xaa-Gly.
EBPs exhibit a lower critical solution temperature (LCST) behavior in which a reversible phase transition is observed depending on temperature. The LCST provides the advantage of using an easy purification method such as inverse transition cycling (ITC) and the advantage of being thermally triggered to self-assemble into particles, gels, fibers and other structures.
Diblocks composed of EBP blocks that have different sequences are used to form self-assembled structures. An EBP diblock copolymer is composed of two EBPs, in which the EBPs have different sequences and different transition temperatures (Tt) to form a self-assembled micellar structure. When the temperature of an EBP diblock copolymer solution increases above a lower Tt, EBPs that have a low Tt become insoluble whereas EBPs that have a high Tt are soluble, and amphiphilic diblock EBPs are self-assembled into micellar structures. EBP diblock copolymers may be fused with other functional peptides, e.g., a cell penetrating peptide capable of penetrating cells, to have functional multivalency as micellar structures.
Soluble EBPs may be used as inert protein-based biomaterials, like poly(ethylene glycol) (PEG), and as drug delivery carriers with drugs or other functional proteins, for advanced drug delivery systems, regenerative medicine, and tissue engineering.
EBPs may be easily purified and have stimuli-triggered phase transitions, allowing for genetic fusion with other functional proteins and exploitation of the advantages of EBPs. For example, EBPs may be fused with an interleukin-1 receptor antagonist (IL-1Ra) to create an injectable drug reservoir for treating osteoarthritis.
In addition, with the advancement of therapeutic EBP fusion proteins, self-assembled micelles of EBP block copolymers are being studied. An EBP diblock copolymer is composed of two different EBP blocks, each of which has a different sequence, configuration and chain length, which allows each EBP block to have a unique transition temperature (Tt). When temperature rises, the EBP block with a low Tt becomes insoluble, while another EBP block with a high Tt becomes soluble above the low Tt. Due to the amphiphilic properties of the EBP diblock copolymer above the low Tt, the EBP diblock copolymer self-assembles into a core-shell micellar nanostructure. In addition, EBP diblock copolymers may be fused with other functional peptides or proteins to become functionally multivalent. Both the core and shell of the EBP micellar nanostructure may be used differently as drug delivery carriers.
Recently, a considerable number of cancer-related diseases have been known to result from abnormal neovascularization in tumors. Physiological neovascularization in organisms is strictly regulated and is only activated under specific conditions. However, excessive formation of blood vessels due to disruption of regulation may lead to diseases such as non-tumor diseases as well as cancers. Under physiological conditions, including development, growth, wound healing, and regeneration, neovascularization is stimulated by vascular endothelial growth factor (VEGF). VEGF binds to two types of VEGF receptors (VEGFRs), including VEGFR1 (fms-like tyrosine kinase-1 or Flt1) and VEGFR2 (kinase insert domain-containing receptor or Flk-1/KDR), present on cell membranes. Selective binding of VEGF to VEGF receptors delivers a growth signal to vascular endothelial cells, which in turn triggers neovascularization.
Therefore, to inhibit neovascularization in various diseases such as tumor growth, cancer metastasis, retinal neovascularization, corneal neovascularization, diabetic retinopathy and asthma, various strategies for anti-neovascularization have been employed. In particular, anti-neovascularization strategies for treatment of ocular neovascularization include initiating a signal that inhibits neovascularization using neovascularization inhibitors such as pigment epithelial-derived factor (PEDF) and caffeic acid (CA), and blocking neovascularization signals by interfering with binding of VEGF to receptors thereof (VEGFRs). In particular, since biomacromolecules and targeting peptides have high affinity for VEGFR1 and competitively bind to VEGFR1 as receptor antagonists, using biomacromolecules or targeting peptides as antibodies may be a challenging strategy related to interfering with binding of VEGF to VEGF receptors.
An anti-Flt1 peptide identified by PS-SPCL (positional scanning-synthetic peptide combinatorial library) screening, one among high throughput screening (HTS) systems, is a hexa-peptide having an amino acid sequence of Gly-Asn-Gln-Trp-Phe-Ile (GNQWFI). The anti-Flt1 peptide, as a VEGFR1-specific antagonist, specifically binds to VEGFR1, which prevents VEGFR1 from interacting with all VEGFR1 ligands, including placental growth factor (PIGF), as well as VEGF. To increase the half-life of the anti-Flt1 peptide in vivo, anti-Flt1 peptide-hyaluronate (HA) conjugates have been studied in connection with the formation of self-assembled micelle structures which encapsulate genistein, dexamethasone or tyrosine-specific protein kinase inhibitors. Although conjugation of the anti-Flt1 peptide with HA polymers increases the half-life of the anti-Flt1 peptide in the body, conjugation efficiency and micellar structures are heterogeneous due to polydisperse HA polymer molecular weights, random distribution, and inconsistency of conjugation efficiency of the anti-Flt1 peptides and the HAs.
The present inventors have continued to study fusion polypeptides for inhibiting neovascularization. As a result, a novel fusion polypeptide in which a peptide targeting vascular endothelial growth factor (VEGF) receptors and an elastin-based polypeptide were fused was developed and the present invention was completed.
Therefore, the present invention has been made in view of the above problems, and it is an objective of the present invention to provide a novel fusion polypeptide for inhibiting neovascularization.
It is another objective of the present invention to provide a self-assembled nanostructure of the fusion polypeptide.
It is still another objective of the present invention to provide a composition for treating diseases caused by neovascularization.
It is yet another objective of the present invention to provide a method of inhibiting neovascularization in individuals.
According to an aspect of the present invention, there is provided a fusion polypeptide for inhibiting neovascularization, including:
a peptide specifically binding to vascular endothelial growth factor (VEGF) receptors; and
a hydrophilic elastin-based polypeptide (hydrophilic EBP) linked to the peptide.
The peptide specifically binding to VEGF receptors may be a peptide that specifically binds to VEGF receptor Flt1 or Flk-1/KDR.
The peptide specifically binding to VEGF receptors may be a peptide that specifically binds to VEGF receptor Flt1 or Flk-1/KDR, and is also called “VEGF receptor-specific peptide” or “VEGF receptor-targeting peptide”. The VEGF receptor-specific peptide may be any of anti-Flt1 or anti-Flk-1/KDR (poly)peptides well known in the art. For example, the peptide may be an anti-Flt1 peptide [SEQ ID NO. 38], but is necessarily limited thereto.
The hydrophilic EBP may be composed of an amino acid sequence represented by Formula 1 or 2 below:
Formula 1
[SEQ ID NO. 1]n; or
Formula 2
[SEQ ID NO. 2]n, wherein
SEQ ID NO. 1 is consisted of [VPGXG VPGXG VPGXG VPGXG VPGXG VPGXG];
SEQ ID NO. 2 is consisted of [VPAXG VPAXG VPAXG VPAXG VPAXG VPAXG];
n is an integer of 1 or more, and represents the number of repeats of SEQ ID NO. 1 or SEQ ID NO. 2; and
X is an amino acid other than proline, is selected from any natural or artificial amino acid when the pentapeptide VPGXG or VPAXG is repeated, and at least one of X is a hydrophilic amino acid.
The hydrophilic EBP may be composed of an amino acid sequence represented by Formula 1 or 2 below:
in Formula 1, n is 1, each X of the pentapeptide repeats is consisted of,
A (Ala), G (Gly), and I (Ile) in a ratio of 1:4:1 [SEQ ID NO. 20];
K (Lys), G (Gly), and I (Ile) in a ratio of 1:4:1 [SEQ ID NO. 22];
D (Asp), G (Gly), and I (Ile) in a ratio of 1:4:1 [SEQ ID NO. 24]; or
E (Glu), G (Gly), and I (Ile) in a ratio of 1:4:1 [SEQ ID NO. 26], or
in Formula 2, n is 1, and the pentapeptide repeats
in Formula 2, n is 1, and each X of the pentapeptide repeats is consisted of,
A (Ala), G (Gly), and I (Ile) in a ratio of 1:4:1 [SEQ ID NO. 21];
K (Lys), G (Gly), and I (Ile) in a ratio of 1:4:1 [SEQ ID NO. 23];
D (Asp), G (Gly), and I (Ile) in a ratio of 1:4:1 [SEQ ID NO. 25]; or
E (Glu), G (Gly), and I (Ile) in a ratio of 1:4:1 [SEQ ID NO. 27].
The hydrophilic EBP may include an amino acid sequence represented by Formula 2 below:
in Formula 2, n is 3, 6, 12 or 24, and the pentapeptide repeats correspond to SEQ ID NO. 41, SEQ ID NO. 42, SEQ ID NO. 43 or SEQ ID NO. 44 and each X of the pentapeptide repeats is composed of A (Ala), G (Gly), and I (Ile) in a ratio of 1:4:1 or
in Formula 2, n is 12, and the pentapeptide repeats
correspond to SEQ ID NO. 451 and each X of the pentapeptide repeats is composed of E (Glu), G (Gly), and I (Ile) in a ratio of 1:4:1.
The fusion polypeptide according to the present invention may further include a hydrophobic elastin-based polypeptide (hydrophobic EBP) linked to the hydrophilic EBP.
That is, the fusion polypeptide may include of the following:
a peptide specifically binding to vascular endothelial growth factor (VEGF) receptors;
a hydrophilic elastin-based polypeptide (hydrophilic EBP) linked to the peptide; and
a hydrophobic elastin-based polypeptide (hydrophobic EBP) linked to the hydrophilic EBP.
The hydrophobic EBP may include an amino acid sequence represented by Formula 1 or 2 below:
Formula 1
[SEQ ID NO. 1]n; or
Formula 2
[SEQ ID NO. 2]n, wherein
SEQ ID NO. 1 is consisted of [VPGXG VPGXG VPGXG VPGXG VPGXG VPGXG];
SEQ ID NO. 2 is consisted of [VPAXG VPAXG VPAXG VPAXG VPAXG VPAXG];
n is an integer of 1 or more, and represents the number of repeats of SEQ ID NO. 1 or SEQ ID NO. 2; and
X is an amino acid other than proline, is selected from any natural or artificial amino acid when the pentapeptide VPGXG or VPAXG is repeated, and at least one of X is a hydrophobic or aliphatic amino acid.
The hydrophobic EBP may be consisted of an amino acid sequence represented by Formula 1 or 2 below:
in Formula 1, n is 1, and each X of the pentapeptide repeats is consisted of,
G (Gly), A (Ala), and F (Phe) in a ratio of 1:3:2 [SEQ ID NO. 29];
K (Lys), A (Ala), and F (Phe) in a ratio of 1:3:2 [SEQ ID NO. 30];
D (Asp), A (Ala), and F (Phe) in a ratio of 1:3:2 [SEQ ID NO. 31];
K (Lys) and F (Phe) in a ratio of 3:3 [SEQ ID NO. 32];
D (Asp) and F (Phe) in a ratio of 3:3 [SEQ ID NO. 33];
H (His), A (Ala), and I (Ile) in a ratio of 3:2:1 [SEQ ID NO. 34];
H (His) and G (Gly) in a ratio of 5:1 [SEQ ID NO. 35]; or
G (Gly), C (Cys), and F (Phe) in a ratio of 1:3:2 [SEQ ID NO. 36].
The hydrophobic EBP may include an amino acid sequence represented by Formula 2 below:
in Formula 2, n is 12, and each X of the pentapeptide repeats is consisted of G (Gly), A (Ala), and F (Phe) in a ratio of 1:3:2 [SEQ ID NO. 46], or
in Formula 2, n is 24, and each X of the pentapeptide repeats is consisted of
G (Gly), A (Ala), and F (Phe) in a ratio of 1:3:2 [SEQ ID NO. 47].
In one embodiment, the fusion polypeptide of the present invention may be composed of an amino acid sequence corresponding to SEQ ID NO. 48, SEQ ID NO. 49, SEQ ID NO. 50 or SEQ ID NO. 51. That is, the fusion polypeptide may be represented as follows:
the fusion polypeptide includes,
an anti-Flt 1 peptide; and a hydrophilic EBP [A1G4I1]3 linked to the anti-Flt1 peptide, and represented by [SEQ ID NO. 48];
an anti-Flt 1 peptide; and a hydrophilic EBP [A1G4I1]6 linked to the anti-Flt1 peptide, and represented by [SEQ ID NO. 49];
an anti-Flt 1 peptide; and a hydrophilic EBP [A1G4I1]12 linked to the anti-Flt1 peptide, and represented by [SEQ ID NO. 50]; or
an anti-Flt 1 peptide; and a hydrophilic EBP [A1G4I1]24 linked to the anti-Flt1 peptide, and represented by [SEQ ID NO. 51].
In another embodiment, the fusion polypeptide of the present invention may include an amino acid sequence corresponding to SEQ ID NO. 52 or SEQ ID NO. 53. That is, the fusion polypeptide may be represented as follows:
the fusion polypeptide includes,
an anti-Flt 1 peptide; a hydrophilic EBP [E1G4I1]12; and a hydrophobic EBP [G1A3F2]12, and represented by [SEQ ID NO. 52]; or
an anti-Flt 1 peptide; a hydrophilic EBP [E1G4I1]12; and a hydrophobic EBP [G1A3F2]24, and represented by [SEQ ID NO. 53].
According to the present invention, the fusion polypeptide composed of a VEGF receptor-specific peptide; a hydrophilic EBP; and a hydrophobic EBP may form a self-assembled nanostructure having a core-shell structure, when the hydrophobic EBP forms a core structure and the hydrophilic EBP and the VEGF receptor-specific peptide form a shell structure by a temperature stimulus.
The self-assembled nanostructure may include a multivalent VEGF receptor-specific peptide as a shell.
Specifically, an anti-Flt 1 peptide which is a VEGF receptor-specific peptide is exemplified. A fusion polypeptide composed of an anti-Flt 1 peptide; a hydrophilic EBP; and a hydrophobic EBP may form a self-assembled nanostructure having a core-shell structure, when the hydrophobic EBP forms a core structure and the hydrophilic EBP and the anti-Flt1peptide form a shell structure by a temperature stimulus.
The self-assembled nanostructure may include a multivalent anti-Flt1 peptide as a shell, which provides greatly enhanced binding affinity to VEGF receptors.
According to another aspect of the present invention, there is provided a composition for treating diseases caused by neovascularization, including the fusion polypeptide.
According to still another aspect of the present invention, there is provided a method of inhibiting neovascularization in individuals, including a step of administering the therapeutic composition to individuals.
When a fusion polypeptide composed of a VEGF receptor-specific peptide; and a hydrophilic EBP is exemplified, the VEGF receptor-specific peptide of the fusion polypeptide may be non-covalently bound to a VEGF receptor to inhibit neovascularization (
In addition, an example of a fusion polypeptide composed of a VEGF receptor-specific peptide; a hydrophilic EBP; and a hydrophobic EBP is as follows.
The fusion polypeptide may form a self-assembled nanostructure having a core-shell structure, when the hydrophobic EBP forms a core structure and the hydrophilic EBP and the VEGF receptor-specific peptide form a shell structure by a temperature stimulus, and
the self-assembled nanostructure may include a multivalent VEGF receptor-specific peptide as a shell, whereby binding affinity between the self-assembled nanostructure and a VEGF receptor increases, and VEGF fails to bind to the VEGF receptor, thereby inhibiting neovascularization.
The diseases caused by neovascularization may be any one or more selected from the group comprising diabetic retinopathy, retinopathy of prematurity, macular degeneration, choroidal neovascularization, neovascular glaucoma, eye diseases caused by corneal neovascularization, corneal transplant rejection, corneal edema, corneal opacity, cancer, hemangioma, hemangiofibroma, rheumatoid arthritis, and psoriasis, but are necessarily limited thereto.
The term “vascular endothelial growth factor (VEGF)” used in the present invention refers to a factor that stimulates new blood vessel formation. VEGF binds to VEGF receptors to deliver a growth signal to vascular endothelial cells, which in turn triggers neovascularization.
The fusion polypeptide of the present invention functions to prevent VEGF from binding to VEGF receptors.
The term “amino acid” used in the present invention refers to a natural or artificial amino acid, preferably a natural amino acid. For example, the amino acid includes glycine, alanine, serine, valine, leucine, isoleucine, methionine, glutamine, asparagine, cysteine, histidine, phenylalanine, arginine, tyrosine, tryptophan and the like.
The properties of these amino acids are well known in the art. Specifically an amino acid exhibits hydrophilicity (negative or positive charge) or hydrophobicity, and also exhibits aliphatic or aromatic properties.
As used herein, abbreviations such as Gly (G) and Ala (A) are amino acid abbreviations. Gly is an abbreviation for glycine, and Ala is an abbreviation for alanine. In addition, glycine is represented by G and alanine by A. The abbreviations are widely used in the art.
In the present invention, “hydrophilic amino acid” is an amino acid exhibiting hydrophilic properties, and includes lysine, arginine and the like.
In addition, “hydrophobic amino acid” is an amino acid exhibiting hydrophobic properties, and includes phenylalanine, leucine and the like.
The term “polypeptide” used herein refers to any polymer chain composed of amino acids. The terms “peptide” and “protein” may be used interchangeably with the term polypeptide, and also refer to a polymer chain composed of amino acids. The term “polypeptide” includes natural or synthetic proteins, protein fragments and polypeptide analogs having protein sequences. A polypeptide may be a monomer or polymer.
The term “phase transition” refers to a change in the state of a material, such as when water turns into water vapor or ice turns into water.
The polypeptide according to the present invention is basically an elastin-based polypeptide (EBP) with stimuli-responsiveness. The “elastin-based polypeptide” is also called “elastin-like polypeptide (ELP)”. The term is widely used in the technical field of the present invention.
In the present specification, Xaa (or X) refers to a “guest residue”. Various types of EBPs according to the present invention may be prepared by variously introducing Xaa.
EBP undergoes a reversible phase transition at a lower critical solution temperature (LCST), also referred to as a transition temperature (Tt). EBPs are highly water-soluble below Tt, but become insoluble when temperature exceeds Tt.
In the present invention, the physicochemical properties of EBPs are mainly controlled by combination of a pentapeptide repeat unit Val-Pro-(Gly or Ala)-Xaa-Gly. Specifically, the third amino acid of the repeat unit is responsible for determining the relative mechanical properties of the EBPs. For example, according to the present invention, the third amino acid Gly is responsible for determining elasticity, or Ala is responsible for determining plasticity. Elasticity and plasticity are properties that appear after a phase transition occurs.
In addition, the hydrophobicity of a guest residue Xaa, the fourth amino acid, and multimerization of a pentapeptide repeat unit all affect Tt.
The EBP according to the present invention may be a polypeptide composed of pentapeptide repeats, and a polypeptide block, i.e., an EBP block, may be formed when the polypeptide is repeated. Specifically, a hydrophilic or hydrophobic EBP block may be formed. The hydrophilic or hydrophobic properties of an EBP block according to the present invention are closely related to the transition temperature of the EBP.
The transition temperature of the EBP is also determined by the amino acid sequence of the EBP and the molecular weight thereof. A number of studies on the relationship between an EBP sequence and Tt have been conducted by Urry et al (see Urry D. W., Luan C.-H., Parker T. M., Gowda D. C., Parasad K. U., Reid M. C., and Safavy A. 1991. TEMPERATURE OF POLYPEPTIDE INVERSE TEMPERATURE TRANSITION DEPENDS ON MEAN RESIDUE HYDROPHOBICITY. J. Am. Chem. Soc. 113: 4346-4348). According to the above reference, when, in a pentapeptide of Val-Pro-Gly-Val-Gly, the fourth amino acid, a “guest residue”, is replaced with a residue that is more hydrophilic than Val, Tt is increased compared to the original sequence. On the other hand, when the guest residue is replaced with a residue that is more hydrophobic than Val, Tt is decreased compared to the original sequence. That is, it was found that a hydrophilic EBP has a high Tt and a hydrophobic EBP has a relatively low Tt. Based on these findings, it has become possible to prepare an EBP having a specific Tt by determining which amino acid is used as the guest residue of an EBP sequence and changing the composition ratio of the guest residue (see PROTEIN-PROTEIN INTERACTIONS: A MOLECULAR CLONING MANUAL, 2002, Cold Spring Harbor Laboratory Press, Chapter 18. pp. 329-343).
As described above, an EBP exhibits hydrophilicity when the EBP has a high Tt, and hydrophobicity when the EBP has a low Tt. Similarly, in the case of the EBP block according to the present invention, it is also possible to increase or decrease Tt by changing an amino acid sequence including guest residues and a molecular weight thereof. Thus, a hydrophilic or hydrophobic EBP block may be prepared.
For reference, an EBP having Tt lower than a body temperature may be used as a hydrophobic block, whereas an EBP having Tt higher than a body temperature may be used as a hydrophilic block. Due to this property of EBPs, the hydrophilic and hydrophobic properties of EBPs may be relatively defined when EBPs are applied to biotechnology.
Taking EBP sequences according to the present invention as an example, when a plastic polypeptide block in which a plastic pentapeptide of Val-Pro-Ala-Xaa-Gly is repeated is compared with an elastic polypeptide block in which an elastic pentapeptide of Val-Pro-Gly-Xaa-Gly is repeated, the third amino acid, Gly, has higher hydrophilicity than Ala. Accordingly, the plastic polypeptide block (elastin-based polypeptide with plasticity: EBPP) exhibits a lower Tt than the elastic polypeptide block (elastin-based polypeptide with elasticity: EBPE).
EBPs according to the present invention, as described above, may exhibit hydrophilic or hydrophobic properties by adjusting Tt and may be charged using charged amino acids.
Fusion polypeptides according to the present invention is schematically shown in
The term “EBP diblock” used herein refers to a block composed of “hydrophilic EBP-hydrophobic EBP”, and is also called “EBP diblock copolymer”, “EBP diblock block”, “diblock EBP” “diblock EBPs” or “diblock EBPPs”.
The present invention relates to a new class of genetically encoded “stimuli-responsive VEGFR-targeting fusion polypeptides”.
In one embodiment, specifically, the fusion polypeptide is composed of an anti-Flt1 peptide acting as a receptor antagonist targeting VEGFR1 and a hydrophilic EBP block as a soluble unimer.
In another embodiment, the fusion polypeptide is composed of an anti-Flt1 peptide acting as a receptor antagonist targeting VEGFR1; a hydrophilic EBP block; and a hydrophobic EBP block. The EBP diblock of the hydrophilic EBP block and the hydrophobic EBP block contributes to the formation of a temperature-triggered core-shell micellar structure.
When using a fusion polypeptide composed of an anti-Flt1 peptide and a hydrophilic EBP block, a strong non-covalent interaction between VEGFR1 and the anti-Flt1 peptide domain of the fusion polypeptide occurs.
In addition, a fusion polypeptide composed of an anti-Flt1 peptide; a hydrophilic EBP block; and a hydrophobic EBP block may form a temperature-triggered core-shell micellar structure with a multivalent anti-Flt1 peptide under physiological conditions, which may increase the binding affinity of the fusion polypeptide for VEGFR1.
Therefore, the fusion polypeptide of the present invention may be presented as a polypeptide drug for treating neovascularization-related diseases.
The fusion polypeptide of the present invention may overcome the following limitations that arise when conventional peptide drugs and peptide-polymer conjugates are applied to in vivo treatment: (1) rapid clearance by proteases; (2) time consuming and costly conjugation and purification; (3) random distribution and (appearing upon polymerization of various polymers and peptide drugs) inconsistent conjugation efficiency; and (4) heterogeneous micellar structures due to polydisperse molecular weights thereof.
The present invention provides a VEGFR-targeting fusion polypeptide composed of thermally responsive elastin-based polypeptides (EBPs) and a vascular endothelial growth factor receptor (VEGFR)-targeting peptide. The fusion polypeptide of the present invention was genetically engineered, expressed and purified, and the physicochemical properties thereof were analyzed. The EBPs were introduced as non-chromatographic purification tags and were also introduced as a stabilizer, like a poly(ethylene glycol) conjugate, for minimizing rapid in vivo degradation of VEGFR1-targeting peptides. In addition, the VEGFR-targeting peptide was introduced to function as a receptor antagonist by specifically binding to VEGFRs. A fusion polypeptide composed of a VEGFR-targeting peptide-hydrophilic EBP block exhibited a soluble unimer form. On the other hand, a fusion polypeptide composed of VEGFR-targeting peptide-hydrophilic EBP block-hydrophobic EBP block exhibited a temperature-triggered core-shell micellar structure with a multivalent VGFR-targeting peptide under physiological conditions. As analyzed by enzyme-linked immunosorbent assay (ELISA), these structures increased the binding affinity of a fusion polypeptide for VEGF receptors (see Examples below). Depending on the spatial display of a VEGFR-targeting peptide, the binding affinity of the VEGFR-targeting peptide to VEGFRs was greatly regulated. The present invention shows how the binding affinity of a VEGFR-targeting peptide can be regulated based on multivalency.
A therapeutic composition including a fusion polypeptide for inhibiting neovascularization according to the present invention is a pharmaceutical composition. The pharmaceutical composition may include the fusion polypeptide and other materials that do not interfere with the function of the composition used in vivo for inhibiting neovascularization. Such other materials are not limited and may include diluents, excipients, carriers and/or other inhibitors of neovascularization.
In some embodiments, the fusion polypeptides for inhibiting neovascularization of the present invention are formulated for conventional human administration, for example, by formulating the fusion polypeptides with a suitable diluent, including sterile water and normal saline.
Administration or delivery of a therapeutic composition according to the present invention may be performed through any route so long as target tissues can be reached through that route. For example, the administration may be performed by direct injection into a target tissue (e.g., cardiac tissue) such as topical or intradermal, subcutaneous, intramuscular, intraperitoneal, intraarterial, intracoronary, intrathymic or intravenous injection, or intravitreal injection. The stability and/or potency of the fusion polypeptide disclosed in the present invention allow for convenient administration routes including subcutaneous, intradermal, intravenous and intramuscular routes.
The present invention provides a method of delivering a fusion polypeptide (e.g., as a part of a composition or formulation described herein) into cells, and a method of treating, alleviating, or preventing progression of a disease in a subject. The term “subject” or “patient” used in the present invention refers to any vertebrate animals, including, without being limited to, humans and other primates (e.g., chimpanzees and other apes and monkey species), farm animals (e.g., cows, sheep, pigs, goats and horses), domestic mammals (e.g., dogs and cats), laboratory animals (e.g., rodents such as mice, rats and guinea pigs) and birds (e.g., domestic, wild and game birds such as chickens, turkeys and poultry, ducks, geese, and the like). In some embodiments, the subject is a mammal.
In another embodiment, the mammal is a human.
A fusion polypeptide or pharmaceutical composition of the present invention may contact a target cell (e.g., a mammalian cell) in vitro or in vivo.
According to yet another aspect of the present invention, there is provided a method of treating or preventing diseases caused by neovascularization, the method including a step of administering a therapeutic composition according to the present invention to individuals.
For clinical use, the fusion polypeptide of the present invention may be administered alone via any suitable route of administration effective to achieve a desired therapeutic result or may be formulated into a pharmaceutical composition. The administration “route” of the oligonucleotides of the present invention may include enteral, parenteral and topical administration or inhalation. Among the administration routes of the fusion polypeptide of the present invention, enteral includes oral, gastrointestinal, intestinal, and rectal. Parenteral routes include ocular injection, intravenous, intraperitoneal, intramuscular, intraspinal, subcutaneous, topical, vaginal, topical, nasal, mucosal and pulmonary administration. The topical route of administration of the fusion polypeptides of the present invention refers to external application of the oligonucleotides into the epidermis, mouth and ears, eyes and nose.
The therapeutic composition may be administered by parenteral, oral, transdermal, sustained release, controlled release, delayed release, suppository, catheter or sublingual administration.
When the fusion polypeptide included in the therapeutic composition is administered in combination with other drugs, the fusion polypeptide may be administered in an amount of 15 μg/kg or less when injected intravenously, and may be administered in an amount of 2.5 μg or less when injected intravitreally.
The present invention is further illustrated by the following additional examples which should not be construed as limiting. It should be understood by those of ordinary skill in the art that various changes to the specific embodiments disclosed may be made without departing from the spirit and scope of the invention in the light of the present invention and that equivalent or similar results may be obtained.
Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art to which this invention belongs. In general, the nomenclature used herein is well known and commonly used in the art.
The above and other objects, features and advantages of the present invention will become more apparent to those of ordinary skill in the art by describing in detail exemplary embodiments thereof with reference to the accompanying drawings, in which:
A pET-21a (+) vector and BL21 (DE3) E. Coli cells were obtained from Novagen Inc. (Madison, Wis., U.S.). Top10 competent cells and calcein-AM were purchased from Invitrogen (Carlsbad, Calif., U.S.) and HUVECs were purchased from American Type Culture Collection (ATCC) (Virginia, U.S.). All customized oligonucleotides were synthesized by Cosmo GeneTech (Seoul, South Korea) and recombinant human VEGF-165 (rhVEGF165) was obtained from Sino Biological Inc. (Beijing, China). Calf intestinal alkaline phosphatase (CIP), BamHI and XbaI were obtained from Fermentas (Ontario, Canada). AcuI and BseRI were purchased from New England Biolabs (Ipswich, Mass., U.S.). T4 DNA ligase was obtained from Elpis Bio-tech (Taejeon, South Korea). DNA miniprep, gel extraction, and PCR purification kits were obtained from Geneall Biotechnology (Seoul, South Korea). “Dyne Agarose High” was obtained from DYNE BIO, Inc. (Seongnam, South Korea). Top10 cells were grown in “TB DRY” media obtained from MO BIO Laboratories, Inc. (Carlsbad. Calif., U.S.). BL21(DE3) cells were grown in “CircleGrow” media obtained from MP Biomedicals (Solon, Ohio, U.S.). “Ready Gels, Tris-HCl 2-20% precast gels” were from Bio-Rad (Hercules, Calif., U.S.). Phosphate buffered saline (PBS, pH 7.4), kanamycin, polyethyleneamine (PEI), FITC-dextran, formalin and bovine serum albumin (BSA) were obtained from Sigma-Aldrich (St Louis, Mo., U.S.). Matrigel was purchased from BD Biosciences (San Diego, Calif., U.S.). Avastin, also known as bevacizumab was purchased from Roche Pharma Ltd. (Reinach, Switzerland). Ketamine was obtained from Huons (Seongnam, South Korea). Xylazine was purchased from BAYER (Leverkusen, Germany). Tropicamide was purchased from Santen Pharmaceutical Co. Ltd (Kita-ku, Osaka, Japan). A stereomicroscope was obtained from Leica (Wetzlar, Germany). Recombinant human VEGF165 protein and recombinant human VEGF R1/Flt-1 F, were purchased from R&D System (Minneapolis, Minn., U.S.). Rabbit anti-human IgG Fc-HRP chimeric protein and 3,3′, 5,5′-tetramethylbenzidine (TMB) was obtained from ThermoFisher (Massachusetts, U.S.).
Different EBPs having a pentapeptide repeat unit of Val-Pro-(Gly or Ala)-Xaa-Gly[VP (G or A)XG] are named as follows. Xaa may be any amino acid except Pro. First, pentapeptide repeats of Val-Pro-Ala-Xaa-Gly (VPAXG) with plasticity are defined as an elastin-based polypeptide with plasticity (EBPP). On the other hand, pentapeptide repeats of Val-Pro-Gly-Xaa-Gly (VPGXG) are called elastin-based polypeptides with elasticity (EBPEs). Second, in [XiYjZk]n, the capital letters in the parentheses represent the single letter amino acid codes of guest residues, i.e., amino acids at the fourth position (Xaa or X) of an EBP pentapeptide, and subscripts corresponding to the capital letters indicate the ratio of the guest residues in an EBP monomer gene as a repeat unit. The subscript number n of [XiYjZk]n represents the total number of repeats of an EBP corresponding to SEQ ID NO. 1 [VPGXG VPGXG VPGXG VPGXG VPGXG VPGXG] or SEQ ID NO. 2[VPAXG VPAXG VPAXG VPAXG VPAXG VPAXG] according to the present invention. For example, EBPP[G1A3F2]12 is an EBPP block including 12 repeats of a pentapeptide unit, SEQ ID NO. 2[VPAXG VPAXG VPAXG VPAXG VPAXG VPAXG], in which a ratio of Gly, Ala, and Phe at the fourth guest residue position (Xaa) is 1:3:2. Finally, EBP-EBP diblock polypeptides are named according to the composition of each block in brackets with a hyphen between blocks as in EBPP[E1G4I1]12-EBPP[G1A3F2]12.
4 μg of a pET-21a vector was digested and dephosphorylated with 50 U of XbaI, 50 U of BamHI and 10 U of a thermosensitive alkaline phosphatase in FastDigest buffer for 20 minutes at 37° C. The digested plasmid DNA was purified using a PCR purification kit, and then was eluted in 40 μl of distilled and deionized water. Two oligonucleotides with XbaI and BamHI compatible sticky ends were designed, i.e., SEQ ID NO. 39 (5′-ctagaaataattttgtttaactttaagaaggaggagtacatatgggctactgataatgatcttcag-3′) and SEQ ID NO. 40 (5-gatcctgaagatcattatcagtagcccatatgtactcctccttcttaaagttaaacaaaattattt-3′). To anneal the two types of oligonucleotides, each oligonucleotide was prepared at a concentration of 2 μM in 50 μl of T4 DNA ligase buffer, heat treated at 95° C. for 2 minutes and then slowly cooled to room temperature over 3 hours. To ligate the annealed dsDNA, i.e., a DNA insert, into multiple cloning sites within the linearized pET-21a vector, 20 pmol of the annealed dsDNA and 0.1 pmol of the linearized pET-21a vector were incubated in T4 DNA ligase buffer containing 1 U of T4 DNA ligase for 30 minutes at 37° C. The modified pET-21a (mpET-21a) vector for cloning and expressing a seamless gene was transformed into Top10 competent cells, followed by plating the Top10 competent cells on a super optimal broth with catabolite repression (SOC) plate supplemented with 50 μg/ml ampicillin. The DNA sequence of the mpET-21a vector was then verified by fluorescent dye terminator DNA sequencing (Applied Biosystems Automatic DNA Sequencer ABI 3730).
EBP sequences having a pentapeptide repeat unit, Val-Pro-(Gly or Ala)-Xaa-Gly, in which the fourth residues were varied in different molar ratios, were designed at the DNA level to optimize Tt below a physiological temperature. The DNA and amino acid sequences of EBPs with various pentapeptide repeat units for 17 EBP libraries are shown in Tables 1 and 2, respectively.
In Table 1, SEQ ID NO. 3 to 10 may be classified as gene sequences for hydrophilic EBP blocks, and SEQ ID NO. 11 to 19 may be classified as gene sequences for hydrophobic EBP blocks, in which Phe and His are incorporated. In Table 2, amino acid SEQ ID NO. 20 to 27 may be classified as hydrophilic EBP blocks, and amino acid SEQ ID NO. 28 to 36, in which Phe and His are incorporated, may be classified as hydrophobic EBP blocks. In particular, in Table 2, SEQ ID NO. 22 and 23 are classified as positively charged hydrophilic EBP blocks, and SEQ ID NO. 24 to 27 are classified as negatively charged hydrophilic EBP blocks. That is, as described above, when the LCST of an EBP is lower than the body temperature, the EBP exhibits hydrophobicity, and when the LCST of an EBP is higher than the body temperature, the EBP exhibits hydrophilicity. Due to this nature of EBPs, the hydrophilic and hydrophobic properties of EBPs may be relatively defined when EBPs are applied to biotechnology.
Different EBPs having a pentapeptide repeat unit, Val-Pro-(Gly or Ala)-Xaa-Gly [where Xaa may be any amino acid except Pro], which are capable of responding to unique stimuli including temperature and pH, were designed at the DNA level. EBPs with plasticity (EBPPs) having a pentapeptide repeat unit of Val-Pro-Ala-Xaa-Gly and EBPs with elasticity (EBPEs) having a pentapeptide repeat unit of Val-Pro-Gly-Xaa-Gly were all cloned to have the same guest residue composition and ratio. Tables 1 and 2 represent the gene and amino acid sequences of different EBPs having respective pentapeptide units. For example, EBPE[G1A3F2]12 and EBPP[G1A3F2]12 not only show almost the same molar mass, but also the fourth residues of these EBP pentapeptide units represent the same combination. In addition, these EBP blocks have different mechanical properties because the third amino acid residues (Ala or Gly) of the pentapeptide units are different. Positively and negatively charged EBPs were prepared by introducing charged amino acids such as Lys, Asp, GIu, and His as guest residues.
To anneal each pair of oligonucleotides encoding various EBPs, each oligonucleotide was prepared at a concentration of 2 μM in 50 μl of T4 DNA ligase buffer, heat treated at 95° C. for 2 minutes and then slowly cooled to room temperature over 3 hours. 4 μg of a modified pET-21a vector was digested and dephosphorylated with 15 U of BseRI and 10 U of FastAP thermosensitive alkaline phosphatase for 30 minutes at 37° C. The digested plasmid DNA was purified using a PCR purification kit, and then was eluted in 40 μl of distilled and deionized water. To ligate the annealed dsDNA, i.e., a DNA insert, into multiple cloning sites within the linearized mpET-21a vector, 90 pmol of the annealed dsDNA and 30 pmol of the linearized mpET-21a vector were incubated in T4 DNA ligase buffer containing 1 U of T4 DNA ligase for 30 minutes at 16° C. The ligated plasmid was transformed into Top10 chemically competent cells, followed by plating the Top10 competent cells on an SOC plate supplemented with 50 μg/ml ampicillin. DNA sequences were then confirmed by DNA sequencing. After all EBP monomer genes were constructed, each EBP gene was synthesized by ligating each of 36 types of repetitive genes (as an insert) into the corresponding vector containing each of the same 36 types of repetitive genes, as follows. A cloning procedure for EBP libraries and fusions thereof are illustrated in
As described above, EBP gene libraries having different DNA sizes were synthesized using the designed plasmid vector and three different restriction endonucleases.
EBP genes and block co-polypeptides thereof were overexpressed in E. coli having a T7 promoter and purified by multiple cycles of inverse transition cycling (ITC).
EBP libraries were characterized.
A pair of oligonucleotides encoding an anti-Flt1 peptide acting as a VEGFR1 antagonist were chemically synthesized by Cosmo Genetech (Seoul, Korea), and linked to an oligonucleotide cassette with cohesive ends including restriction sites recognized by AcuI and BseRI. An oligonucleotide cassette encoding the anti-Flt1 peptide was rationally designed to have no restriction sites recognized by BseRI, XbaI, AcuI and BamHI for seamless gene cloning, as shown in Table 3.
In Table 4, the sequences, gene lengths and molecular weights of fusion polypeptides with a hydrophilic EBP block or an EBP diblock of hydrophilic EBP block-hydrophobic EBP block are shown.
Each plasmid containing an EBP with restriction sites recognized by BseRI, XbaI, AcuI and BamHI, and the oligonucleotide cassette were used to create genes for the fusion polypeptide libraries of anti-Flt1-EBPP[A1G4I1]3n and anti-Flt1-EBP diblock blocks. First, to anneal a pair of oligonucleotides encoding an anti-Flt1 peptide, each oligonucleotide was prepared at a concentration of 2 μM in 50 μl of T4 DNA ligase buffer, heat treated at 95° C. for 2 minutes and then the reaction solution was slowly cooled to room temperature over 3 hours. To clone the anti-Flt1-EBPP[A1G4I1]3n, a plasmid vector encoding EBPP[A1G4I1]3n was digested with 15 U of BseRI in CutSmart buffer for 30 minutes at 37° C. The digested plasmid DNA was purified using a PCR purification kit, and then dephosphorylated with 10 U of FastAP as a thermosensitive alkaline phosphatase in CutSmart buffer for 1 hour at 37° C. The digested and dephosphorylated plasmid DNA was purified using a PCR purification kit, and then eluted in 40 μl of distilled and deionized water. Ligation was performed by incubating 90 pmol of the purified insert and 30 pmol of the linearized vector in T4 DNA ligase buffer containing 1 U of T4 DNA ligase at 16° C. for 30 minutes. The product was transformed into Top10 chemically competent cells and the cells were plated on SOC plates supplemented with 50 μg/ml ampicillin Transformants were initially screened by diagnostic restriction digestion on an agarose gel and further confirmed by DNA sequencing as described above.
Similarly, to clone anti-Flt1-EBP diblock blocks with hydrophobic blocks of different lengths, plasmid vectors encoding EBPP[G1A3F2]n were digested with 10 U of XbaI and 15 U of BseRI in CutSmart buffer for 30 minutes at 37° C. The digested plasmid DNA was purified using a PCR purification kit, and then dephosphorylated with 10 U of FastAP as a thermosensitive alkaline phosphatase in CutSmart buffer for 1 hour at 37° C. The digested and dephosphorylated plasmid DNA was purified using a PCR purification kit, and then eluted in 40 μl of distilled and deionized water. 4 μg of EBPP[E1G4I1]n genes were digested with 10 U of XbaI and 15 U of AcuI in CutSmart buffer for 30 minutes at 37° C. After digestion, the reaction product was separated by agarose gel electrophoresis and an insert was purified using a gel extraction kit. Ligation was performed by incubating 90 pmol of the purified insert and 30 pmol of the linearized vector in T4 DNA ligase buffer containing 1 U of T4 DNA ligase at 16° C. for 30 minutes. The product was transformed into Top10 chemically competent cells and the cells were plated on SOC plates supplemented with 50 μg/ml ampicillin Transformants were initially screened by diagnostic restriction digestion on an agarose gel and further confirmed by DNA sequencing. Plasmid vectors encoding anti-Flt1-EBP diblock blocks were prepared using BseRI, and ligation and confirmation of ligation were performed as described above.
E. coli strain BL21(DE3) cells were transformed with each vector containing an EBP, anti-Flt1-EBPP[A1G4I1]3n or an anti-Flt1-EBP diblock block, and then inoculated in 50 ml of CircleGrow media supplemented with 50 μg/ml ampicillin Preculture was performed in a shaking incubator at 200 rpm overnight at 37° C. 500 ml of CircleGrow media with 50 μg/ml ampicillin was then inoculated with 50 ml of the precultured CircleGrow media and incubated in a shaking incubator at 200 rpm for 16 hours at 37° C. When optical density at 600 nm (OD600) reached 1.0, overexpression of an EBP gene or a block polypeptide gene thereof was induced by addition of IPTG at a final concentration of 1 mM. The cells were centrifuged at 4500 rpm for 10 minutes at 4° C. The expressed EBPs and block polypeptides thereof were purified by inverse transition cycling (ITC) as reported previously. The cell pellet was resuspended in 30 ml of HEPES buffer, and the cells were lysed by sonication for 10 s in 20 s intervals (VC-505, Sonics & Materials, Inc, Danbury, Conn.) on ice. The cell lysate was centrifuged in a 50 ml centrifuge tube at 13,000 rpm for 15 min at 4° C. to precipitate the insoluble debris of the cell lysate. Supernatant containing soluble EBPs was then transferred to a new 50 ml centrifuge tube and centrifuged with 0.5% w/v of PEI at 13,000 rpm for 15 minutes at 4° C. to precipitate nucleic acid contaminants. The inverse phase transition of the EBPs were triggered by adding sodium chloride at a final concentration of 4 M, and aggregated EBPs were separated from the lysate solution by centrifugation at 13,000 rpm for 15 minutes at 4° C. The aggregated EBPs were resuspended in cold PBS buffer, and the EBP solutions were centrifuged at 13,000 rpm for 15 minutes at 4° C. to remove any aggregated protein contaminants. These aggregation and resuspension processes were repeated 5 to 10 times until EBP purity reached about 95%, and the purity was determined by SDS-polyacrylamide gel electrophoresis (SDS-PAGE).
As shown in
Modified pET-21a (mpET-21a) plasmids harboring EBPP[A1G4I1]n, EBPP[E1G4I1]n or EBPP[G1A3F2]n (where the subscript number n of [XiYjZk]n is 6, 12, 18, 24, 30 or 36) were seamlessly cloned using standard molecular biology methodology. In particular, multimerization and fusion of EBPP genes were executed using recursive directional ligation (RDL) to construct genes encoding EBPPs with different molecular weights and EBPP block copolymers.
In VEGFR-targeting peptide (anti-Flt1 peptide)-hydrophilic EBP-fusion polypeptide, anti-Flt1-EBPP[A1G4I1]3, 6, 12, 24 is soluble under physiological conditions and acts as a VEGFR antagonist to compete with VEGF, thereby inhibiting delivery of neovascularization signals to cells (
The purity of EBPs, anti-Flt1-EBPP[A1G4I1]3n and anti-Flt1-EBP diblock blocks was determined by SDS-PAGE, and gel permeation chromatography (GPC) with a high-performance liquid chromatography (HPLC) 1260 series instrument (Agilent Technologies, Palo Alto, Calif., U.S.) using a Shodex GPC OHpak SB-804 HQ column (Showa Denko Co., Tokyo, Japan). Deionized water at 20° C. was used as an eluent at a flow rate of 1 ml/min and the GPC column was maintained at 20° C. Low dispersity pullulan in a range of 5,900 to 200,000 g/mol was used as a standard. A series of EBPs, anti-Flt1-EBPP[A1G4I1]3n and anti-Flt1-EBP diblock blocks were analyzed using a refractive index detector (RID) and variable wavelength detector (VWD) at 280 nm. An effect of temperature on the inverse phase transition of various EBPs, anti-Flt1-EBPP[A1G4I1]3n and anti-Flt1-EBP diblock blocks at 25 μM concentration in PBS was determined by measuring OD350 using a Cary 100 Bio UV/Vis spectrophotometer equipped with a multi-cell thermoelectric temperature controller (Varian Instruments, Walnut Creek, Calif.) between 10 to 85° C. at a heating rate of 1° C./min Self-assembly behaviors of anti-Flt1-EBPP[E1G4I1]12-[G1A3F2]12 and anti-Flt1-EBPP[E1G4I1]12-[G1A3F2]24 from soluble unimers into micelles were characterized using a temperature-controlled Nano ZS90 (ZEN3690) dynamic light scattering (DLS) instrument (Malvern instruments, Worcestershire, UK), and the hydrodynamic radius (RH) thereof at 25 μM in PBS was measured in 11 successive runs at each temperature in a temperature range from 18 to 50° C. at a heating rate of 1° C./min. In addition, Tt thereof is defined as the onset temperature for phase transition, and calculated from each DLS plot.
Genes for fusion polypeptides composed of an anti-Flt1 peptide and hydrophilic EBP blocks with different lengths were constructed by molecular cloning and the lengths of those genes digested with XbaI and BseRI were confirmed by agarose gel electrophoresis as shown in
Tt values in Table 5 are determined by measuring the inflection points of thermal profiles in
In general, EBPP[A1G4I1]3n and anti-Flt1-EBPP[A1G4I1]3n without polar amino acid residues exhibit Tt higher than 37° C. under physiological conditions because Ala, Gly and Ile were introduced to the EBPPs as the guest residue of the repetitive pentapeptide unit of the EBPPs in a ratio of 1:4:1. Anti-Flt1-EBPP[A1G4I1]3n was hydrophilic and VEGFR binding-fusion polypeptides thereof were soluble under physiological conditions, which allowed the polypeptides to specifically bind to VEGFRs without any steric hindrance. Thus, the fusion polypeptides of the present invention may act as VEGFR antagonists against VEGF. Furthermore, when the effect of EBPP block length and ionic strength on thermal responsiveness was analyzed, as the EBP block length of EBPP[A1G4I1]3n and anti-Flt1-EBPP[A1G4I1]3n, and sodium chloride concentration in PBS increased, Tt thereof decreased. In particular, the Tt of anti-Flt1-EBPP[A1G4I1]3n was much lower than that of EBPP[A1G4I1]3n because Gly-Asn-Gln-Trp-Phe-Ile (GNQWFI) of an anti-Flt1 peptide sequence for targeting VEGFRs was hydrophobic, resulting in a decrease in the Tt of anti-Flt1-EBPP[A1G4I1]3. For example, the Tt of anti-Flt1-EBPP[A1G4I1]12 and the Tt of anti-Flt1-EBPP[A1G4I1]24 were about 18 and 11° C. lower than those of EBPP[A1G4I1]12 and EBPP[A1G4I1]24 in PBS, respectively. A Tt difference (DTt) between EBPP[A1G4I1]3 and anti-Flt1-EBPP[A1G4I1]3 was more than 36° C. in PBS with 2 M sodium chloride, whereas DTt between EBPP[A1G4I1]3 and anti-Flt1-EBPP[A1G4I1]3 was 23° C. in PBS with 1 M sodium chloride. Therefore, as EBPP[A1G4I1] block length became shorter, the Tt of anti-Flt1-EBPP[A1G4I1]3n was greatly decreased irrespective of various concentrations of sodium chloride. This data indicates that the effect of hydrophobicity of the anti-Flt1 peptide on the thermal transition of the EBPP[A1G4I1] block is potentially greater.
Next, the properties of fusion polypeptides composed of VEGFR-targeting peptide (anti-Flt1 peptide)-hydrophilic EBP-hydrophobic EBP are described. Two different genes, which encode a fusion polypeptide composed of “anti-Flt1 peptide” and “amphiphilic EBP diblock” of hydrophilic EBP-hydrophobic EBP having hydrophobic EBP blocks with various chain lengths, were constructed using RDL, a seamless molecular cloning method. The full lengths of those genes digested by XbaI and BseRI were confirmed by agarose gel electrophoresis as shown in
Tt values in Table 6 are determined by measuring the inflection points of thermal profiles in
As the concentration of anti-Flt1-EBP diblock blocks increased, the first Tt and the second Tt gradually decreased. In general, the temperature-triggered phase transition of anti-Flt1-EBP diblock copolypeptides occurs twice, because aliphatic- and hydrophobic EBPP[A1G3F2] block having a low Tt and polar- and hydrophilic EBPP[E1G4I1] block having a high Tt exhibit different thermal properties. The phase transition of anti-Flt1-EBPP[E1G4I1]12-[G1A3F2]12 occurred at 36.2 and 81.2° C. at the 25 μM concentration, whereas the phase transition of anti-Flt1-EBPP[E1G4I1]12-[G1AaF2]24 occurred at 28.0 and 78.0° C. at the same concentration. This data indicates that the doubled block length of the hydrophobic EBPP[A1G3F2] has a significant effect on the first Tt and the second Tt, lowering the same by 8.2 and 3.2° C., respectively. In particular, diblock polypeptides of EBPP[E1G4I1]12-[G1A3F2]12 and EBPP[E1G4I1]12-[G1A3F2]24 without anti-Flt1 fusion, as a control, exhibited a first Tt of only 39.0 and 29.1° C. without an additional phase transition, as shown in
In accordance with the unique thermal transition of anti-Flt1-EBP diblock copolypeptides, the self-assembly behaviors of anti-Flt1-EBPP[E1G4I1]12-[G1A3F2]12 and anti-Flt1-EBPP[E1G4I1]12-[G1A3F2]24 from soluble unimers into micelles were characterized by dynamic light scattering (DLS). The hydrodynamic radius (RH) thereof at 25 μM in PBS was measured in 11 successive runs at each temperature in a temperature range from 18 to 50° C. at a heating rate of 1° C./min. Tt thereof was defined as the onset temperature for phase transition, calculated from each DLS plot in
Referring to Table 7, the first aggregation of fusion polypeptides increases the hydrodynamic radius thereof due to micelle formation.
Anti-Flt1-EBP diblock copolypeptides existed in soluble unimer forms below the first Tt of 36° C. for anti-Flt1-EBPP[E1G4I1]12-[G1A3F2]12 and below the first Tt of 27° C. for anti-Flt1-EBPP[E1G4I1]12-[G1A3F2]24, and the hydrodynamic radius (RH) thereof at 25 μM in PBS was about 10 nm. As temperature increased above the first Tr, the RH thereof instantaneously increased in a range of 160 and 240 nm at a slightly higher temperature than the first Tt, then decreased to 28.4 and 43.6 nm. The anti-Flt1-EBP diblock copolypeptides formed metastable micelles due to non-equilibrium thermodynamics of amphiphile-based self-assembly and different hydrophilic-to-hydrophobic block length ratios, and then the copolypeptides formed stable micelles with constant RH values even at 50° C. because self-assembly thereof reached equilibrium. The RH of an anti-Flt1-EBPP[E1G4I1]12-EBPP[G1A3F2]24 micelle was 15.2 nm larger than that of the anti-Flt1-EBPP[E1G4I1]12-EBPP[G1A3F2]12 micelle due to the doubled block length of EBPP[G1A3F2] and the bigger aggregated domain of the EBPP[G1A3F2] block at the core of the micellar structure thereof. Furthermore, to determine the critical micelle concentrations (CMCs) of the anti-Flt1-EBP diblock copolypeptides, the micelle sizes thereof at various concentrations in a range of 0.1 to 25 μM were measured at 20° C. below Tt and 37° C. above Tt. Under environmental conditions of 0.5 μM and 37° C., the anti-Flt1-EBPP[E1G4I1]12-[G1A3F2]12 still formed a metastable micelle with a RH of ˜125 nm and the anti-Flt1-EBPP[E1G4I1]12-EBPP[G1A3F2]24 formed a stabilized micelle with a RH of ˜44 nm. However, no micelle formation was observed for the two anti-Flt1-EBP diblock copolypeptides at 0.1 μM and 37° C., indicating that the 0.1 μM concentration was lower than CMCs thereof, and the CMCs were in a range of 0.1 to 0.5 μM. Therefore, the anti-Flt1-EBP diblock copolypeptides formed temperature-triggered core-corona micellar structures with multivalent anti-Flt1 peptides for targeting Flt1 under physiological conditions because of the amphiphilic properties of hydrophilic EBPP[E1G4I1] and hydrophobic EBPP[G1A3F2]. In particular, in the anti-Flt1-EBP diblock copolypeptides, different block lengths of hydrophobic EBPP[G1A3F2] finely controlled micellar size, which affected the binding affinity thereof to Flt1, resulting in high adhesion.
Specific binding of anti-Flt1-EBPP[A1G4I1]3n (n: 1, 2, 4, and 8) and anti-Flt1-EBP diblock copolypeptides to Flt1 was determined by enzyme-linked immunosorbent assay (ELISA). First, to coat a 96 well plate with recombinant human VEGF165 protein (rhVEGF165) (M.W. 38.4 kDa) present in a disulfide-linked homodimer, 50 μl of a solution containing the rhVEGF165 at a concentration of 0.5 μg/ml was added to the 96 well plate, and the plated was incubated at 4° C. overnight. The wells of the 96 well plate coated with the rhVEGF165 were washed with PBS containing 0.05% Tween-20 to completely remove unattached rhVEGF165, and then the wells were incubated with PBS containing 3 wt % BSA at room temperature for 2 hours to block the surface of each well, which was not coated with the rhVEGF165. After incubation, the wells were washed with PBS containing 0.05% Tween-20 to remove unbound BSA. Next, to impart specific binding affinity between an anti-Flt1 peptide and Flt1 (VEGFR1), a recombinant human Flt1-F, chimeric protein (M.W. 200.0 kDa) present in a disulfide-linked homodimer at a concentration of 0.5 μg/ml was pre-incubated with (1) anti-Flt1-EBPP[A1G4I1]3n (n: 1, 2, 4, and 8) in PBS containing 1 wt % BSA or with (2) anti-Flt1-EBP diblock copolypeptides (anti-Flt1-EBPP[E1G4I1]12-EBPP[G1A3F2]12 and anti-Flt1-EBPP[E1G4I1]12-EBPP[G1A3F2]24) with hydrophobic blocks of different lengths. In this case, the pre-incubation was carried out at room temperature for 2 hours at different concentrations within a range of 0.5 to 500 μM. Thereafter, the mixed solution was added to rhVEGF165-coated wells, followed by additional incubation at room temperature for 2 hours. The EBPP[A1G4I1]12 and EBP diblock copolypeptide (EBPP[E1G4I1]12-EBPP[G1A3F2]12 and anti-Flt1-EBPP[E1G4I1]12-EBPP[G1A3F2]24) with hydrophobic blocks (having the same concentration) of different lengths were used as a standard. Each well was washed with PBS supplemented with 0.05% Tween-20 to remove Flt1-F, protein that was not bound to rhVEGF165 on the surface of the well. Whether human Flt1-F, protein was specifically bound to the rhVEGF165-coated well was determined by measuring the absorbance of oxidized chromogenic substrates upon protein-antibody binding at 450 nm using rabbit anti-human IgG Fc-horseradish peroxidase (HRP) conjugates as a secondary antibody. PBS (containing 0.3 w % BSA) diluted with anti-human IgG Fc-HRP was added to each well and incubated for 1 hour at room temperature, followed by washing 8 times with PBS containing 0.05% Tween-20, 3,3′,5,5′-tetramethylbenzidine (TMB) was added to each well to indirectly determine the degree of specific binding of Flt1-Fc protein to VEGF by measuring the specific interaction between the Flt1-F, protein and the anti-human IgG Fc-HRP protein, and HRP-catalyzed oxidation of the TMB. The color intensity of the oxidized TMB was measured at 450 nm. Each ELISA experiment was performed three times for reproducibility.
The specific binding properties of a fusion polypeptide of VEGFR-targeting peptide (anti-Flt1 peptide)-hydrophilic EBP are examined. As shown in
Next, the binding properties of fusion polypeptides of VEGFR-targeting peptide (anti-Flt1 peptide)-hydrophilic EBP-hydrophobic EBP are examined With specific binding of soluble anti-Flt1-EBPP[A1G4I1]3n to a human Flt1-Fc chimeric protein, anti-Flt1-EBP diblock blocks (anti-Flt1-EBPP[E1G4I1]12-EBPP[G1A3F2]12 and anti-Flt1-EBPP[E1G4I1]12-EBPP[G1A3F2]24) with hydrophobic blocks of different lengths formed temperature-triggered core-shell micellar structures with multivalent anti-Flt1 peptides under physiological conditions. Multivalent anti-Flt1 located on the outer shell of the formed self-assembled micelles increased the binding affinity of the fusion polypeptides to human Flt1 (VEGFR1). As measured by enzyme-linked immunosorbent assay (ELISA) in
In vitro tubing assay of HUVECs using soluble anti-Flt1-EBPP[A1G4I1]12 was performed to evaluate effects of the soluble anti-Flt1-EBPP[A1G4I1]12 copolypeptides on proliferation, migration and tube formation of endothelial cells. For Matrigel coating, 200 μl of 8.7 mg/ml Matrigel was added to a 48 well plate and incubated at 37° C. for 1 hour to become solidified. To label HUVECs with fluorescence, HUVECs were incubated with 10 μM calcein-AM at 37° C. for 15 minutes and washed with PBS several times. The calcein-labeled HUVECs at 2×104 cells/well were grown on the Matrigel-coated wells, and incubated at 37° C. for 4 hours with 50 ng/ml recombinant human rhVEGF165 and anti-Flt1-EBPP[A1G4I1]12 as a Flt1-specific antagonist at different concentrations. After incubation, it was determined whether proliferation, migration and tube formation of endothelial cells were stimulated. To clarify to what extent anti-Flt1-EBPP[A1G4I1]12 could inhibit tube formation of HUVECs, the same concentration of EBPP[A1G4I1]12 was assessed as a control. In addition, Avastin, a recombinant humanized monoclonal antibody (mAb) against VEGF, was used as another control to compare therapeutic efficacy for anti-neovascularization based on the therapeutic efficacy of anti-Flt1-EBPP[A1G4I1]12, as a Flt1-specific antagonist. The tube formation of HUVECs was photographed with Micromanipulator (Olympus, Tokyo, Japan), and quantified by measuring whole tube lengths in three random fields per well with Image lab software (Bio-Rad Laboratories, Hercules, Calif., USA). When the tubing assay was performed, the tube formation of HUVECs incubated in PBS for 4 hours was used as a control. The experiment was repeated three times.
As shown in
6- to 8-week-old female C57BL-6 mice were anesthetized with intraperitoneal injection of ketamine at 100 mg/kg and xylazine at 10 mg/kg, and the pupils were dilated with 5 mg/ml tropicamide, and 532 nm laser diode (150 to 210 mW, 0.1 sec, 50 to 100 μM) was applied to each fundus to induce choroidal neovascularization in vivo. Multiple burns were performed in the 6, 9, 12, and 3 o'clock positions of the posterior pole of the eye with a slit-lamp delivery system. Production of bubbles at the time of laser, which indicates Bruch's membrane rupturing, is an important factor in obtaining the CNV model. To evaluate an effect of anti-Flt1-EBPP[A1G4I1]3n copolypeptides on anti-neovascularization in a laser-induced choroidal neovascularization model in vivo, the CNV model mice were injected in an intravitreal manner with PBS as a vehicle, EBPP[A1G4I1]12 or various concentrations of anti-Flt1-EBPP[A1G4I1]12 once a day for 5 days and anesthetized after 14 days with an intraperitoneal injection of ketamine at 100 mg/kg and xylazine at 10 mg/kg. The mice were treated with retro-orbital injection of 100 μl ultrapure water containing 25 mg/ml FITC-dextran. Enucleated eyes were then fixed in 10% formalin for 30 minutes at room temperature. The cornea, iris, lens, and vitreous humor were gently removed under a stereomicroscope (Leica, Wetzlar, Germany). Four radial incisions were made in the dissected retina, which was then flattened with a coverslip. Each in vivo anti-neovascularization experiment was performed with three replicates.
By ELISA and HUVEC tubing assay, it was demonstrated that anti-Flt1-EBPP[A1G4I1]3n fusion polypeptides retained anti-neovascularization activity as an antagonist against VEGFR1. The present inventors hypothesized that anti-Flt1-EBPP[A1G4I1]3n fusion polypeptides might show a therapeutic activity with respect to neovascularization-related eye diseases (in particular, retinal neovascular disease, age-related macular degeneration (AMD)). Intravitreal injection of anti-Flt1-EBPP[A1G4I1]12 was evaluated for the suppression of laser-induced choroidal neovascularization (CNV), which was an animal model for AMD, in C57BL-6 mice. Daily injection of protein solutions started immediately after laser injury and maintained for 5 days. Injection of a vehicle (PBS) or EBPP[A1G4I1]12 was used as a negative control. CNV lesion volumes were imagined and evaluated with fluorescein isothiocyanate (FITC)-dextran perfused whole choroidal flat-mounts at day 14 after laser injury (
Binding affinity of a targeting ligand against a growth factor receptor (GFR) in cells is important for various diseases associated with cell growth such as neovascularization, because the binding affinity determines whether intracellular signaling will proceed. In the present invention, VEGFR-targeting fusion polypeptides, which are composed of thermally responsive elastin-based polypeptides (EBPs) and vascular endothelial growth factor receptor (VEGFR)-targeting peptides, were genetically manipulated, expressed, and purified and the physicochemical properties thereof were analyzed. The EBPs were introduced as non-chromatographic purification tags and also introduced as a stabilizer, like a poly(ethylene glycol) conjugate, for minimizing rapid in vivo degradation of VEGFR-targeting peptides. In addition, the VEGFR-targeting peptide was introduced to function as a receptor antagonist by specifically binding to VEGFRs.
A fusion polypeptide composed of VEGFR-targeting peptide (anti-Flt1 peptide)-hydrophilic EBP exhibited a soluble unimer form. On the other hand, a fusion polypeptide composed of VEGFR-targeting peptide (anti-Flt1 peptide)-hydrophilic EBP-hydrophobic EBP exhibited a temperature-triggered core-shell micellar structure with a multivalent VGFR-targeting peptide under physiological conditions. As analyzed by enzyme-linked immunosorbent assay (ELISA), this structure greatly increased the binding affinity of the fusion polypeptide for VEGF receptors. Depending on the spatial display of a VEGFR-targeting peptide, the binding affinity of the fusion polypeptides to VEGFRs was greatly regulated.
An anti-Flt1-EBPP[A1G4I1]3n fusion polypeptide (anti-Flt1 peptide-hydrophilic EBP), which existed as a soluble unimer form below a transition temperature, showed a high anti-neovascularization effect in a CNV model as compared with a EBPP block as a control. In addition, an anti-Flt1-EBP diblock fusion polypeptide (anti-Flt1 peptide-hydrophilic EBP-hydrophobic EBP) formed a temperature-triggered, self-assembled multivalent micellar nanostructure under physiological conditions, resulting in a great difference in the degree of inhibition with respect to specific binding between Flt1-Fc and VEGF depending on the stability of the micellar nanostructure thereof. In the tube formation assay of HUVECs in vitro, anti-Flt1-EBPP[A1G4I1]12 greatly reduced tube formation, whereas EBPP[A1G4I1]12 had no significant effect on tube formation, which was due to specific interactions between the anti-Flt1-EBPP[A1G4I1]12 and Flt1 (VEGFR1) on the HUVEC membrane. Finally, in the laser-induced CNV model of mice, anti-Flt1-EBPP[A1G4I1]12 showed a high anti-neovascularization effect. Therefore, this fusion polypeptide and the self-assembled multivalent micellar nanostructure thereof with an anti-Flt1 may be used as a therapeutic polypeptide targeting neovascularization, such as treatment of retinal, corneal, choroidal neovascularization, tumor growth, cancer metastasis, diabetic retinopathy, and asthma.
A fusion polypeptide for inhibiting neovascularization of the present invention can provide a new direction for a drug delivery system for anti-neovascularization, such as treatment of retinal, corneal, choroidal neovascularization, tumor growth, cancer metastasis, diabetic retinopathy, and asthma.
Number | Date | Country | Kind |
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10-2016-0042655 | Apr 2016 | KR | national |
10-2016-0135510 | Oct 2016 | KR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/KR2016/011757 | 10/19/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/175939 | 10/12/2017 | WO | A |
Number | Name | Date | Kind |
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20070265197 | Furgeson et al. | Nov 2007 | A1 |
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10-2012-0094867 | Aug 2012 | KR |
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20180208642 A1 | Jul 2018 | US |