Generating Orally Active Galanin Analogues with Analgesic Activities

Robertson, Charles R.; Pruess, Timothy H.; Grussendorf, Erin; White, H. Steve; Bułaj, Grzegorz

doi:10.1002/cmdc.201100574

Cited by 7 publications

(5 citation statements)

References 37 publications

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“…The starting point for this project was our previous finding that an incorporation of lipoamino acids into GAL and NPY analogues yielded compounds that suppressed seizures in the brain. − Here, we hypothesized that replacing lipidation with dPEGylation will restrict penetration of the neuropeptide analogues into the brain, while their activities in the PNS would be retained. Since our initial SAR studies focused on dPEGylation of a well-characterized lead compound Gal-B2, we first describe a rational design and synthesis of Gal-B2-dPEG 24 that contains both a lipoamino acid and the dPEG 24 -lysine residue .…”

Section: Resultsmentioning

confidence: 99%

“…Anticonvulsant neuropeptides offer attractive templates to engineer peptide-based therapeutics for many neurological diseases . Previously, our group improved the central nervous system (CNS) bioavailability of neuropeptides galanin (GAL), neurotensin (NT), neuropeptide Y (NPY) and neuropeptide W (NPW) via a combination of lipidization and cationization that resulted in analogues that penetrated across the blood–brain barrier (BBB) yielding potent antiepileptic activities (Figure ). − Whereas GAL and NPY suppress epileptic seizures by binding to their respective receptors expressed within the brain, − both peptides are also thought to produce analgesia through their receptors expressed in the peripheral nervous system (PNS). − Galanin and its major receptors, subtype 1 (GalR1) and subtype 2 (GalR2), are expressed in sites of pain mediation outside the brain, including the dorsal root ganglion and the dorsal horn of the spinal cord . Both GalR1- and GalR2-preferring agonists produce inhibitory effects on nociception. ,− It is noteworthy that GalR3 may have less or no effects on peripheral antinociception activity, since low levels of GalR3 are found in both the dorsal root ganglion and spinal cord .…”

Section: Introductionmentioning

confidence: 99%

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Incorporation of Monodisperse Oligoethyleneglycol Amino Acids into Anticonvulsant Analogues of Galanin and Neuropeptide Y Provides Peripherally Acting Analgesics

Zhang¹,

Klein²,

Metcalf³

et al. 2013

Mol. Pharmaceutics

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Delivery of neuropeptides into the central and/or peripheral nervous systems supports development of novel neurotherapeutics for the treatment of pain, epilepsy and other neurological diseases. Our previous work showed that the combination of lipidization and cationization applied to anticonvulsant neuropeptides galanin (GAL) and neuropeptide Y (NPY) improved their penetration across the blood-brain barrier yielding potent antiepileptic lead compounds, such as Gal-B2 (NAX 5055) or NPY-B2. To dissect peripheral and central actions of anticonvulsant neuropeptides, we rationally designed, synthesized and characterized GAL and NPY analogues containing monodisperse (discrete) oligoethyleneglycol-lysine (dPEG-Lys). The dPEGylated analogues Gal-B2-dPEG(24), Gal-R2-dPEG(24) and NPY-dPEG(24) displayed analgesic activities following systemic administration, while avoiding penetration into the brain. Gal-B2-dPEG(24) was synthesized by a stepwise deprotection of orthogonal 4-methoxytrityl and allyloxycarbonyl groups, and subsequent on-resin conjugations of dPEG(24) and palmitic acids, respectively. All the dPEGylated analogues exhibited substantially decreased hydrophobicity (expressed as logD values), increased in vitro serum stabilities and pronounced analgesia in the formalin and carrageenan inflammatory pain assays following systemic administration, while lacking apparent antiseizure activities. These results suggest that discrete PEGylation of neuropeptides offers an attractive strategy for developing neurotherapeutics with restricted penetration into the central nervous system.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Incorporation of Monodisperse Oligoethyleneglycol Amino Acids into Anticonvulsant Analogues of Galanin and Neuropeptide Y Provides Peripherally Acting Analgesics

Zhang¹,

Klein²,

Metcalf³

et al. 2013

Mol. Pharmaceutics

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“…Placing the palmitoyl group at Ser10 of relaxin-3 B-chain (37) also showed a similar drop in binding to RXFP3 as 36, which could be a result of steric hindrance, where palmitoyl group in close proximity to Arg12 might prevent efficient interaction of Arg12 with RXFP3. It is evident that both spacer and lipid positions can impact on receptor binding similar to the observations made in the development of systemically stable liraglutide, semaglutide (Madsen et al, 2007;Lau et al, 2015) and galanin (Bulaj et al, 2008;Robertson et al, 2012). It should be noted however, that the competition binding assays were conducted in the presence of 1% BSA, as lack of BSA led to too high background reading from non-specific binding in the assays.…”

Section: Discussionsupporting

confidence: 62%

Targeting of relaxin-3 analogues to the brain for pharmacological modulation of neurosignalling

Lee¹

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Relaxin-3, a member of the insulin/relaxin superfamily, has been shown to be involved in modulating several neurophysiological process including food intake, stress, addiction, arousal, memory and learning in animal models. Its sequence is highly evolutionary conserved, which strongly suggests an important physiological function. Elucidation of the relaxin-3 three-dimensional structure showed that relaxin-3 adopts a structure similar to insulin, in which the two peptide chains are linked by two inter-chain and one intra-chain disulfides. Residues vital for binding to its cognate receptor, relaxin family peptide 3 receptor (RXFP3), are found in the helical region of the B-chain whereas the C-terminal tail residues of the B-chain are important for activation of the receptor. Truncation of five residues from the C-terminus results in an antagonist, and antagonists and agonists have been important for studying relaxin-3 function. However, the animal studies to date have almost exclusively been conducted via intracerebroventricular injection as these peptides do not efficiently cross the blood-brain barrier (BBB). The BBB is a highly regulated barrier consisting of tight junctions between endothelial cells that prevents paracellular diffusion of most molecules into the brain, and it is decorated with transporters that pump out unwanted products. Many strategies for increasing brain delivery have been utilised over the years, including increasing lipophilicity and positive charge of the drug lead to facilitate membrane permeability and the use of molecular 'Trojan horses'. These 'Trojan horses' can be nonspecific in nature, like cell penetrating peptides, or specifically target receptors expressed on the BBB to enter the brain through receptor-mediated transcytosis. The main aim of this thesis was to design a series of relaxin-3 analogues based solely on the B-chain with increased potential for crossing the BBB when introduced through the systemic circulation, and with an ability to modulate food intake in mice models. In order to achieve this aim, structure-activity relationship studies were first conducted on the single-chain relaxin-3 antagonist (R3 B1-22R) to further understand the binding determinants of this variant. Using Fmoc-peptide synthesis modifications, including an alanine scan, were introduced and there effect on binding evaluated through competition binding assays. There were similarities between the antagonist residues involved in binding to RXFP3 and the relaxin-3 agonist residues, but additional residues are involved in the antagonist and the binding conformations were distinct between the agonist and antagonist. Since linear relaxin-3 B-chain variants are unstructured in solution and easily degraded in serum, we employed several strategies to reintroduce structure into the single-chain analogues. These included substitution with helical promoting residues (Aib), global cyclisation, molecular grafting, and crosslinking of side chains through lactam bonds or hydrocarbon stapling, in order to improve s...

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“…Antisense oligonucleotides to galanin can suppress axotomy‐induced upregulation of galanin‐like immunoreactivity in DRG neurons (Ji et al, ). On the other hand, endogenous galanin exhibits analgesic properties after combination with its receptors in the central and peripheral nervous systems (Robertson et al, ). Administration of galanin reduced both acute and chronic nociception as well as pain transmission in spinal cord and arcuate nucleus of the hypothalamus (Qinyang et al, ).…”

Section: Galanin Ameliorates Sports‐induced Stress and Injury‐inducedmentioning

confidence: 99%

Beneficial effects of neuropeptide galanin on reinstatement of exercise‐induced somatic and psychological trauma

Fang

Guo

et al. 2016

J of Neuroscience Research

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Galanin is a versatile neuropeptide that is distinctly upregulated by exercise in exercise-related tissues. Although benefits from exercise-induced upregulation of this peptide have been identified, many issues require additional exploration. This Review summarizes the information currently available on the relationship between galanin and exercise-induced physical and psychological damage. On the one hand, body movement, exercise damage, and exercise-induced stress and pain significantly increase local and circulatory galanin levels. On the other hand, galanin plays an exercise-protective role to inhibit the flexor reflex and prevent excessive movement of skeletal muscles through enhancing response threshold and reducing acetylcholine release. Additionally, elevated galanin levels can boost repair of the exercise-induced damage in exercise-related tissues, including peripheral nerve, skeletal muscle, blood vessel, skin, bone, articulation, and ligament. Moreover, elevated galanin levels may serve as effective signals to buffer sport-induced stress and pain via inhibiting nociceptive signal transmission and enhancing pain threshold. This Review deepens our understanding of the profitable roles of galanin in exercise protection, exercise injury repair, and exercise-induced stress and pain. Galanin and its agonists may be used to develop a novel preventive and therapeutic strategy to prevent and treat exercise-induced somatic and psychological trauma. © 2016 Wiley Periodicals, Inc.

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Generating Orally Active Galanin Analogues with Analgesic Activities

Cited by 7 publications

References 37 publications

Incorporation of Monodisperse Oligoethyleneglycol Amino Acids into Anticonvulsant Analogues of Galanin and Neuropeptide Y Provides Peripherally Acting Analgesics

Incorporation of Monodisperse Oligoethyleneglycol Amino Acids into Anticonvulsant Analogues of Galanin and Neuropeptide Y Provides Peripherally Acting Analgesics

Targeting of relaxin-3 analogues to the brain for pharmacological modulation of neurosignalling

Beneficial effects of neuropeptide galanin on reinstatement of exercise‐induced somatic and psychological trauma

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