A GLP-1 receptor agonist conjugated to an albumin-binding domain for extended half-life

Evaluation of ABD-Linked RM26 Conjugates for GRPR-Targeted Drug Delivery

Targeting the gastrin-releasing peptide receptor (GRPR) with the bombesin analogue RM26, a 9 aa peptide, has been a promising strategy for cancer theranostics, with recent success in radionuclide imaging of prostate cancer. However, therapeutic application of the short peptide RM26 would require a longer half-life to prevent fast clearance from the circulation. Conjugation to an albumin-binding domain (ABD) is a viable strategy to extend the in vivo half-life of peptides and proteins. We previously reported an ABD-fused RM26 peptide targeting GRPR (ABD-RM26 Gen 1) that showed prolonged and stable tumor uptake over 144 h; however, the observed high kidney uptake indicated that the conjugate's binding to albumin was reduced and that this could be an obstacle for its use as a delivery system for targeted therapy, especially for radiotherapy. Here, we have designed, produced, and preclinically evaluated a series of novel ABD-RM26 conjugates with the aim of improving the conjugate's binding to albumin and decreasing the kidney uptake. We developed three second-generation constructs with varying formats, differing in the relative positions of the targeting moieties and the radionuclide chelator. The produced conjugates were radiolabeled with indium-111 and evaluated in vitro and in vivo. All constructs displayed improved biophysical characteristics, biodistribution, and lower kidney uptake compared to previously reported first-generation molecules. The ABD-RM26 Gen 2A conjugate showed the best biodistribution profile with a nearly 6-fold reduction in kidney uptake. However, the ABD-RM26 Gen 2A conjugate's binding to GRPR was compromised. This conjugate's assembly of albumin- and GRPR-binding moieties might be used for further development of drug conjugates for targeted therapy/radiotherapy of GRPR-expressing cancers.

Recombinant production of interleukin-1 receptor antagonist in fusion to albumin binding domain with potential affinity to human serum albumin

Background and purpose

Anakinra must be injected daily due to its short half-life and this leads to lower patient compliance. Therefore, the aim of this study was to produce an interleukin-1 receptor antagonist (IL-1Ra) with albumin binding domain (ABD) as a novel fusion protein and evaluate its binding ability to albumin and its biological effects.

Experimental approach

The three-dimensional structure of IL-1Ra-ABD was predicted by MODELLER software and its interaction with IL-1R was evaluated by the HADDOCK server. The expression of IL-1Ra-ABD was performed in E. coli in fusion with intein 1 of pTWIN1 in soluble form and then purified. The affinity of IL-1Ra-ABD to human serum albumin (HSA) was determined on native-PAGE, and its release percent toward time was evaluated. Moreover, an MTT assay was used to determine the antagonizing properties of recombinant IL-1Ra-ABD against IL-1β in A375 and HEK293 cell lines.

Findings/Results

The stable complex of IL-1Ra-ABD with IL-1R established the absence of steric hindrance due to the addition of ABD to IL-1Ra. The expression induction of intein 1-IL-1Ra-ABD using 0.1 mM IPTG at 15 °C, and its cleavage represented bands approximately in 50 and 23 kDa. Furthermore, about 78% of IL-1Ra-ABD was attached to the HSA after 2 h of incubation, and the MTT assay showed no significant differences between the effects of IL-1Ra-ABD and native IL-1Ra in cell survival.

Conclusions and implications

The production of soluble IL-1Ra-ABD with no significant differences in IL-1Ra antagonizing effects was successfully performed. IL-1Ra-ABD showed suitable interaction with HSA and was released over time. However, the half-life of IL-1Ra-ABD in vivo must be determined in the subsequent investigations.

Effect of feeding sodium butyrate to beef female cows during pre- and post-partum period on concentrations of glucagon-like peptides in plasma and colostrum

The objective of this study was to evaluate the effect of feeding beef cows with sodium butyrate during the late pregnancy and early post-partum periods on concentrations of glucagon-like peptide (GLP)-1 and 2 in plasma, colostrum, and transition milk. Twelve Japanese Black female cows were fed concentrate feed without (CON; n = 6) or with (BUTY; n = 6) sodium butyrate supplementation at 1.1% of dietary dry matter from -60 d relative to the expected parturition date to 4 d after parturition. Plasma total cholesterol concentration was higher for the BUTY than for the CON (P = 0.04). In addition, plasma GLP-1 concentration was higher for the BUTY than for the CON at 3 d after calving (P < 0.05). This study showed for the first time that GLP-1 is present in the colostrum of Japanese Black cows at higher concentrations as compared to in plasma (P < 0.01). On the other hand, no treatment effect was observed for concentrations of metabolite and hormone in colostrum and transition milk. In summary, feeding beef cows with sodium butyrate during the late gestation and early post-partum period likely increases plasma GLP-1 concentrations post-partum without affecting the components of colostrum and transition milk.

Human serum albumin binders: A piggyback ride for long-acting therapeutics

Human serum albumin (HSA) is the most abundant protein in the blood and has desirable properties as a drug carrier. One of the most promising ways to exploit HSA as a carrier is to append an albumin-binding moiety (ABM) to a drug for in situ HSA binding upon administration. Nature- and library-derived ABMs vary in size, affinity, and epitope, differentially improving the pharmacokinetics of an appended drug. In this review, we evaluate the current state of knowledge regarding various aspects of ABMs and the unique advantages of ABM-mediated drug delivery. Furthermore, we discuss how ABMs can be specifically modulated to maximize potential benefits in clinical development.

Recent advancements in pharmacological strategies to modulate energy balance for combating obesity

The prevalence of obesity along with its related metabolic diseases has increased globally in recent decades. Obesity originates from a heterogeneous physiological state, which is further complicated by the influence of factors such as genetic, behavioural, and environmental. Lifestyle interventions including exercise and diet have limited success, necessitating the development of pharmacological approaches. Mechanistically, strategies target either reducing energy intake or increasing consumption through metabolism boosting. Current drugs lower energy intake via inducing satiety or inhibiting substrate absorption, while targeting mitochondria or cytosolic energy sensors has shown limited success due to toxicity. Nonshivering thermogenesis (NST) has provided hope for activating these processes selectively without significant side effects. The internet-based marketing of plant-based formulations for enhancing metabolism has surged. This review compiles scientific articles, magazines, newspapers, and online resources on anti-obesity drug development. Combination therapy of metabolic boosters and established anti-obesity compounds appears to be a promising future approach that requires further research.

Affibody-conjugated 5-fluorouracil prodrug system preferentially targets and inhibits HER2-expressing cancer cells

Overexpression of HER2 is associated with cancer phenotypes, such as proliferation, survival, metastasis and angiogenesis, and has been validated as a therapeutic target. However, only a portion of patients benefited from anti-HER2 treatments, and many would develop resistance. A more effective HER2 targeted therapeutics is needed. Here, we adopted a prodrug system that uses 5-fluorocytosine (5-FC) and a HER2-targeting scaffold protein, Z_HER2:2891, fused with yeast cytosine deaminase (Fcy) to target HER2-overexpressing cancer cells and to convert 5-FC to a significantly more toxic chemotherapeutic, 5-fluorouracil (5-FU). We cloned the coding gene of Z_HER2:2891 and fused with those of ABD (albumin-binding domain) and Fcy. The purified Z_HER2:2891-ABD-Fcy fusion protein specifically binds to HER2 with a Kd value of 1.6 nM Z_HER2:2891-ABD-Fcy binds to MDA-MB-468, SKOV-3, BT474, and MC38-HER2 cells, which overexpress HER2, whereas with a lower affinity to HER2 non-expresser, MC38. Correspondingly, the viability of HER2-expressing cells was suppressed by relative low concentrations of Z_HER2:2891-ABD-Fcy in the presence of 5-FC, and the IC₅₀ values of Z_HER2:2891-ABD-Fcy for HER2 high-expresser cells were approximately 10-1000 fold lower than those of non-HER2-targeting Fcy, and ABD-Fcy. This novel prodrug system, Z_HER2:2891-ABD-Fcy/5-FC, might become a promising addition to the existing class of therapeutics specifically target HER2-expressing cancers.

Design and evaluation of GLP-1 receptor G-protein biased agonist with prolonged efficacy on diabetes

AIM

Glucagon-like peptide-1 receptor agonists (GLP-1RAs) have emerged as potent drug development target for treating diabetes and obesity. Here, we designed and evaluated novel long-acting GLP-1R G protein biased agonist with potent clinical application.

MAIN METHODS

GLP-1R G-protein biased sequences were screened via a high-throughput autocrine-based strategy and then fused to Exendin (9-39). These fusion peptides were further performed with site-specific modification. Surface plasmon resonance (SPR) measurements, GLP-1R activation potencies and plasma stability tests were applied to screen optimal candidate. Acute and chronic hypoglycemic and insulinotropic activities of selected agent were evaluated in diabetic and obese rodent animals.

MAIN FINDINGS

AX09 exert highest binding affinities for GLP-1R extracellular domain (GLP-1R ECD). Further in vitro plasma stability and GLP-1R activation assays demonstrated better potency of AX18. Acute pharmacodynamic evaluation of AX18 demonstrated the promising insulinotropic and hypoglycemic activities which were exhibited in a dose-dependent manner. Prolonged hypoglycemic efficacies of AX18 were also observed in both hypoglycemic duration test and multiple oral glucose tolerance tests (OGTTs) in the diabetic mice. Further pharmacokinetic test in cynomolgus monkeys exhibited that the half-life of AX18 was more than 6 days. Once weekly treatment of AX18 in diabetic mice for 8-week achieved significantly improved %HbA1C, insulin resistance, glucose tolerance, β-cells and diabetic retinal injury. Chronic treatment of AX18 in diet-induced obese (DIO) mice also exhibited beneficial efficacies on %HbA1C, inflammation-related factors lowering, and weight gains.

CONCLUSION

AX18, as a novel GLP-1R G protein biased agonist, exhibited potency for treating diabetes mellitus and its complications.

Comparative Preclinical Evaluation of HER2-Targeting ABD-Fused Affibody® Molecules 177Lu-ABY-271 and 177Lu-ABY-027: Impact of DOTA Position on ABD Domain

Radiolabeled Affibody-based targeting agent ¹⁷⁷Lu-ABY-027, a fusion of an anti-HER2 Affibody molecule with albumin binding domain (ABD) site-specifically labeled at the C-terminus, has demonstrated a promising biodistribution profile in mice; binding of the construct to albumin prevents glomerular filtration and significantly reduces renal uptake. In this study, we tested the hypothesis that site-specific positioning of the chelator at helix 1 of ABD, at a maximum distance from the albumin binding site, would further increase the strength of binding to albumin and decrease the renal uptake. The new construct, ABY-271 with DOTA conjugated at the back of ABD, has been labelled with ¹⁷⁷Lu. Targeting properties of ¹⁷⁷Lu-ABY-271 and ¹⁷⁷Lu-ABY-027 were compared directly. ¹⁷⁷Lu-ABY-271 specifically accumulated in SKOV-3 xenografts in mice. The tumor uptake of ¹⁷⁷Lu-ABY-271 exceeded uptake in any other organ 24 h and later after injection. However, the renal uptake of ¹⁷⁷Lu-ABY-271 was two-fold higher than the uptake of ¹⁷⁷Lu-ABY-027. Thus, the placement of chelator on helix 1 of ABD does not provide desirable reduction of renal uptake. To conclude, minimal modification of the design of Affibody molecules has a strong effect on biodistribution, which cannot be predicted a priori. This necessitates extensive structure-properties relationship studies to find an optimal design of Affibody-based targeting agents for therapy.

S3-2, a novel long-lasting oxyntomodulin derivative, exerts improvement on diabesity and renal injury through activating GLP-1 and glucagon receptors

AIMS

To prolong the short lifespan of oxyntomodulin (OXM) for treating obesity and diabetes, we designed a novel fused OXM analog, containing an albumin-binding sequence, a protease cleavable tetrapeptide, and a mutated OXM.

MAIN METHODS

We screened two albumin-binding sequences (S3 and S6) to construct OXM derivatives, termed S3-2 (with two cysteines) and S6-0 (without cysteine). After peptides were synthesized, isothermal titration calorimetry (ITC) was applied to assess binding-affinity for HSA. Further in vivo acute efficacies evaluation and candidate selection were performed in diabetic db/db mice via oral glucose tolerance test (OGTT) and glucose-lowering duration test. Chronic efficacy test of selected candidate was also performed in diabetic mice.

RESULTS

Firstly, S3-2 and S6-0 with purity over 99% were prepared. ITC measurements demonstrated that S3-2 and S6-0 associate with HSA with high-affinity (K_d = 12.81 ± 1.11 nM and 26.98 ± 2.39 nM, respectively). Then hypoglycemic efficacies showed deoxidation S3-2 (S3-2re) showed longer hypoglycemic duration than the oxidation one (S3-2ox), and better blood glucose level (BGL) control effect than S6-0. OGTTs in diabetic mice revealed the glucose-lowering efficacies of S3-2re were similar to Liraglutide. The protracted antidiabetic effects of S3-2re were further confirmed by multiple OGTTs in db/db mice. Furthermore, twice weekly injection of S3-2re to db/db mice achieved beneficial effects on body weight gain, glucose tolerance, postprandial BGL and obesity. Moreover, S3-2 produces significantly protective effects on the impaired renal functions of the diabetic mice.

CONCLUSION

S3-2re exhibits outstanding therapeutical potential as a candidate drug for treating the obesity and diabetes.

Preclinical Evaluation of the GRPR-Targeting Antagonist RM26 Conjugated to the Albumin-Binding Domain for GRPR-Targeting Therapy of Cancer

The targeting of gastrin-releasing peptide receptors (GRPR) was recently proposed for targeted therapy, e.g., radiotherapy. Multiple and frequent injections of peptide-based therapeutic agents would be required due to rapid blood clearance. By conjugation of the GRPR antagonist RM26 (D-Phe-Gln-Trp-Ala-Val-Gly-His-Sta-Leu-NH2) to an ABD (albumin-binding domain), we aimed to extend the blood circulation of peptides. The synthesized conjugate DOTA-ABD-RM26 was labelled with indium-111 and evaluated in vitro and in vivo. The labelled conjugate was stable in PBS and retained specificity and its antagonistic function against GRPR. The half-maximal inhibitory concentration (IC50) of natIn-DOTA-ABD-RM26 in the presence of human serum albumin was 49 ± 5 nM. [111In]In-DOTA-ABD-RM26 had a significantly longer residence time in blood and in tumors (without a significant decrease of up to 144 h pi) than the parental RM26 peptide. We conclude that the ABD-RM26 conjugate can be used for GRPR-targeted therapy and delivery of cytotoxic drugs. However, the undesirable elevated activity uptake in kidneys abolishes its use for radionuclide therapy. This proof-of-principle study justified further optimization of the molecular design of the ABD-RM26 conjugate.

Purification and characterization of a long-acting ciliary neurotrophic factor via genetically fused with an albumin-binding domain

Ciliary neurotrophic factor (CNTF) is a promising candidate for the treatment of neurodegenerative or metabolic diseases, but suffers rapid clearance in body. Herein we constructed a new long-acting recombinant human CNTF (rhCNTF) by genetic fusion with an albumin-binding domain (ABD) through a flexible peptide linker, hoping to endow the new molecule prolonged serum circulation time by binding with endogenous human serum albumin (HSA) and then utilizing the naturally long-half-life property of HSA. This fused protein rhCNTF-ABD was expressed in Escherichia coli mainly in the soluble form and purified through a two-step chromatography, with purity of 95% and a high yield of 90-100 mg/L culture. The in vitro binding ability of rhCNTF-ABD with HSA was firstly verified by incubation of the two components together followed by HP-SEC analysis. ABD-fused rhCNTF showed similar secondary and tertiary structure as the parent protein. It retained approximately 94.1% of the native bioactivity as demonstrated via CCK-8 cell viability assay analysis. In vivo studies in SD rats were performed and the terminal half-life of 483.89 min for rhCNTF-ABD was determined, which is about 14 folds longer than that of rhCNTF (34.28 min) and comparable with 20 k-40 kDa PEGylated rhCNTFs. The new constructed rhCNTF-ABD represents a potential therapeutic modality, and the proposed strategy may also have useful applications for other long-lasting biopharmaceutics' design.

Affibody Molecules in Biotechnological and Medical Applications

Affibody molecules are small (6.5-kDa) affinity proteins based on a three-helix bundle domain framework. Since their introduction 20 years ago as an alternative to antibodies for biotechnological applications, the first therapeutic affibody molecules have now entered clinical development and more than 400 studies have been published in which affibody molecules have been developed and used in a variety of contexts. In this review, we focus primarily on efforts over the past 5 years to explore the potential of affibody molecules for medical applications in oncology, neurodegenerative, and inflammation disorders, including molecular imaging, receptor signal blocking, and delivery of toxic payloads. In addition, we describe recent examples of biotechnological applications, in which affibody molecules have been exploited as modular affinity fusion partners.

The Use of Gene Ontology Term and KEGG Pathway Enrichment for Analysis of Drug Half-Life

A drug's biological half-life is defined as the time required for the human body to metabolize or eliminate 50% of the initial drug dosage. Correctly measuring the half-life of a given drug is helpful for the safe and accurate usage of the drug. In this study, we investigated which gene ontology (GO) terms and biological pathways were highly related to the determination of drug half-life. The investigated drugs, with known half-lives, were analyzed based on their enrichment scores for associated GO terms and KEGG pathways. These scores indicate which GO terms or KEGG pathways the drug targets. The feature selection method, minimum redundancy maximum relevance, was used to analyze these GO terms and KEGG pathways and to identify important GO terms and pathways, such as sodium-independent organic anion transmembrane transporter activity (GO:0015347), monoamine transmembrane transporter activity (GO:0008504), negative regulation of synaptic transmission (GO:0050805), neuroactive ligand-receptor interaction (hsa04080), serotonergic synapse (hsa04726), and linoleic acid metabolism (hsa00591), among others. This analysis confirmed our results and may show evidence for a new method in studying drug half-lives and building effective computational methods for the prediction of drug half-lives.

Bioconjugation – using selective chemistry to enhance the properties of proteins and peptides as therapeutics and carriers

Both peptide and protein therapeutics are becoming increasingly important for treating a wide range of diseases. Functionalisation of theseviasite-selective chemical modification leads to enhancement of their therapeutic properties.

Strategic approaches to optimizing peptide ADME properties

Development of peptide drugs is challenging but also quite rewarding. Five blockbuster peptide drugs are currently on the market, and six new peptides received first marketing approval as new molecular entities in 2012. Although peptides only represent 2% of the drug market, the market is growing twice as quickly and might soon occupy a larger niche. Natural peptides typically have poor absorption, distribution, metabolism, and excretion (ADME) properties with rapid clearance, short half-life, low permeability, and sometimes low solubility. Strategies have been developed to improve peptide drugability through enhancing permeability, reducing proteolysis and renal clearance, and prolonging half-life. In vivo, in vitro, and in silico tools are available to evaluate ADME properties of peptides, and structural modification strategies are in place to improve peptide developability.