As
drug discovery moves increasingly toward previously “undruggable”
targets such as protein–protein interactions, lead compounds
are becoming larger and more lipophilic. Although increasing lipophilicity
can improve membrane permeability, it can also incur serious liabilities,
including poor water solubility, increased toxicity, and faster metabolic
clearance. Here we introduce a new efficiency metric, especially relevant
to “beyond rule of 5” molecules, that captures, in a
simple, unitless value, these opposing effects of lipophilicity on
molecular properties. Lipophilic permeability efficiency (LPE) is
defined as log D
7.4
dec/w – m
lipocLogP + b
scaffold, where log D
7.4
dec/w is the
experimental decadiene–water distribution coefficient (pH 7.4),
cLogP is the calculated octanol–water partition coefficient,
and m
lipo and b
scaffold are scaling factors to standardize LPE values across different cLogP
metrics and scaffolds. Using a variety of peptidic and nonpeptidic
macrocycle drugs, we show that LPE provides a functional assessment
of the efficiency with which a compound achieves passive membrane
permeability at a given lipophilicity.
Macrocyclic peptides are considered large enough to inhibit “undruggable” targets, but the design of passively cell-permeable molecules in this space remains a challenge due to the poorly understood role of molecular size on passive membrane permeability. Using split-pool combinatorial synthesis, we constructed a library of cyclic, per-N-methlyated peptides spanning a wide range of calculated lipohilicities (0 < AlogP < 8) and molecular weights (~800 Da < MW < ~1200 Da). Analysis by the parallel artificial membrane permeability assay revealed a steep drop-off in apparent passive permeability with increasing size in stark disagreement with current permeation models. This observation, corroborated by a set of natural products, helps define criteria for achieving permeability in larger molecular size regimes and suggests an operational cutoff, beyond which passive permeability is constrained by a sharply increasing penalty on membrane permeation.
It is well established that intramolecular hydrogen bonding and N-methylation play important roles in the passive permeability of cyclic peptides, but other structural features have been explored less intensively. Recent studies on the oral bioavailability of the cyclic heptapeptide sanguinamide A have raised the question of whether steric occlusion of polar groups via β-branching is an effective, yet untapped, tool in cyclic peptide permeability optimization. We report the structures of 17 sanguinamide A analogues designed to test the relative contributions of β-branching, N-methylation, and side chain size to passive membrane permeability and aqueous solubility. We demonstrate that β-branching has little effect on permeability compared to the effects of aliphatic carbon count and N-methylation of exposed NH groups. We highlight a new N-methylated analogue of sanguinamide A with a Leu substitution at position 2 that exhibits solvent-dependent flexibility and improved permeability over that of the natural product.
Cyclic peptide natural products contain a variety of conserved, nonproteinogenic structural elements such as d-amino acids and amide N-methylation. In addition, many cyclic peptides incorporate γ-amino acids and other elements derived from polyketide synthases. We hypothesized that the position and orientation of these extended backbone elements impact the ADME properties of these hybrid molecules, especially their ability to cross cell membranes and avoid metabolic degradation. Here we report the synthesis of cyclic hexapeptide diastereomers containing γ-amino acids (e.g., statines) and systematically investigate their structure-permeability relationships. These compounds were much more water-soluble and, in many cases, were both more membrane permeable and more stable to liver microsomes than a similar non-statine-containing derivative. Permeability correlated well with the extent of intramolecular hydrogen bonding observed in the solution structures determined in the low-dielectric solvent CDCl3, and one compound showed an oral bioavailability of 21% in rat. Thus, the incorporation of γ-amino acids offers a route to increase backbone diversity and improve ADME properties in cyclic peptide scaffolds.
Synthetic and natural cyclic peptides provide a testing ground for studying membrane permeability in nontraditional drug scaffolds. Cyclic peptomers, which incorporate peptide and N-alkylglycine (peptoid) residues, combine the stereochemical and geometric complexity of peptides with the functional group diversity accessible to peptoids. We synthesized cyclic peptomer libraries by split-pool techniques, separately permuting side chain and backbone geometry, and analyzed their membrane permeabilities using the parallel artificial membrane permeability assay. Nearly half of the side chain permutations had permeability coefficients (P) > 1 × 10 cm/s. Some backbone geometries enhanced permeability due to their ability to form more stable intramolecular hydrogen bond networks compared with other scaffolds. These observations suggest that hexameric cyclic peptomers can have good passive permeability even in the context of extensive side chain and backbone variation, and that high permeability can generally be achieved within a relatively wide lipophilicity range.
The effect of peptide-to-peptoid substitutions on the passive membrane permeability of an N-methylated cyclic hexapeptide is examined. In general, substitutions maintained permeability but increased conformational heterogeneity. Diversification with nonproteinogenic side chains increased permeability up to 3-fold. Additionally, the conformational impact of peptoid substitutions within a β-turn are explored. Based on these results, the strategic incorporation of peptoid residues into cyclic peptides can maintain or improve cell permeability, while increasing access to diverse side-chain functionality.
Large macrocyclic peptides can achieve surprisingly high membrane permeability,a lthough the properties that govern permeability in this chemical space are only beginning to come into focus.W eg enerated two libraries of cyclic decapeptides with stable cross-b conformations,and found that peptoid substitutions within the b-turns of the macrocycle preserved the rigidity of the parent scaffold, whereas peptoid substitutions in the opposing b-strands led to "chameleonic" species that were rigid in nonpolar media but highly flexible in water.B oth rigid and chameleonic compounds showed high permeability over aw ide lipophilicity range,w ith peak permeabilities differing significantly depending on scaffold rigidity.Our findings indicate that modulating lipophilicity can be used to engineer favorable ADME properties into both rigid and flexible macrocyclic peptides,and that scaffold rigidity can be used to tune optimal lipophilicity.
Cyclic peptide (CP) natural products provide useful model systems for mapping "beyond-Rule-of-5" (bRo5) space. We identified the phepropeptins as natural product CPs with potential cell permeability. Synthesis of the phepropeptins and epimeric analogues revealed much more rapid cellular permeability for the natural stereochemical pattern. Despite being more cell permeable, the natural compounds exhibited similar aqueous solubility as the corresponding epimers, a phenomenon explained by solvent-dependent conformational flexibility among the natural compounds. When analyzing the polarity of the solution structures we found that neither the number of hydrogen bonds nor the total polar surface area accurately represents the solvation energies of the high and low dielectric conformations. This work adds to a growing number of natural CPs whose solvent-dependent conformational behavior allows for a balance between aqueous solubility and cell permeability, highlighting structural flexibility as an important consideration in the design of molecules in bRo5 chemical space.
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