N-(tert-But­oxy­carbon­yl)-O-allyl-l-seryl-α-amino­isobutyryl-l-valine methyl ester: a protected tripeptide with an allyl­ated serine residue

Gebreslasie, H.G.; Jacobsen, Ø.; Görbitz, C.H.

doi:10.1107/S0108270111029647

organic compounds

STRUCTURAL
CHEMISTRY

ISSN: 2053-2296

Volume 67| Part 9| September 2011| Pages o359-o363

doi:10.1107/S0108270111029647

N-(tert-Butoxycarbonyl)-O-allyl-L-seryl-α-aminoisobutyryl-L-valine methyl ester: a protected tripeptide with an allylated serine residue

Hadgu Girmay Gebreslasie,^a,^b ‡ Øyvind Jacobsen ^c ‡ and Carl Henrik Görbitz ^a ^*

^aDepartment of Chemistry, University of Oslo, PO Box 1033 Blindern, N-0315 Oslo, Norway, ^bDepartment of Medicine–Medical Biochemistry, College of Health Sciences, Mekelle University, PO Box 1871, Mekelle-Tigray, Ethiopia, and ^cSchool of Pharmacy, University of Oslo, PO Box 1068 Blindern, N-0316 Oslo, Norway
^*Correspondence e-mail: c.h.gorbitz@kjemi.uio.no

(Received 23 June 2011; accepted 22 July 2011; online 6 August 2011)

The title compound [systematic name (6S,12S)-methyl 6-(allyloxymethyl)-12-isopropyl-2,2,9,9-tetramethyl-4,7,10-trioxo-3-oxa-5,8,11-triazatridecan-13-oate], C₂₁H₃₇N₃O₇, containing the little studied O-allyl-L-serine residue [Ser(All)], crystallizes in the monoclinic space group C2 with one molecule in the asymmetric unit. The compound is an analogue of the Ser140-Val142 segment of the water channel aquaporin-4 (AQP4). It forms a distorted type-II β-turn with a P_II–3_10L–P_II backbone conformation (P_II is polyproline II). The overall backbone conformation is markedly different from that of the CO(Pro139)–Val142 stretch of rat AQP4, but is quite similar to the corresponding segment of human AQP4, despite significant differences at the level of the individual residues. The side chain of the Ser(All) residue adopts a gauche conformation relative to the backbone CO—C^α and C^α—N bonds. The H atoms of the two CH₂ groups in the Ser(All) side chain are almost eclipsed. The crystal packing of the title compound is divided into one-molecule-thick layers, each layer having a hydrophilic core and distinct hydrophobic interfaces on either side.

Comment

The title peptide, (I), was prepared as part of an ongoing effort (Jacobsen et al., 2009 ) to synthesize analogues of the Pro138-Gly144 segment of the extracellular loop C of the water channel aquaporin-4 (AQP4) (Hasegawa et al., 1994 ; Jung et al., 1994 ; Hiroaki et al., 2006 ), which has emerged as an important target for the treatment of brain oedema (Nielsen et al., 1997 ; Manley et al., 2000 ; Amiry-Moghaddam et al., 2003 ; Amiry-Moghaddam & Ottersen, 2003 ). The residues Pro139 and Val142 are thought to mediate adhesive interactions between AQP4 molecules in contiguous cell membranes (Hiroaki et al., 2006; Engel et al., 2008 ; Tani et al., 2009 ). The electron diffraction structure of rat AQP4 (rAQP4) revealed that the segment Ser140-Gly144 forms a short 3₁₀-helix [Protein Data Bank (PDB) code 2D57 (Hiroaki et al., 2006) and PDB code 2ZZ9 (Tani et al., 2009)]. We believe that compounds structurally mimicking a loop C segment containing at least one of the residues mediating adhesion can potentially have affinity for AQP4 and serve as lead compounds for the development of selective AQP4 ligands and, eventually, AQP4 inhibitors. (I) may be regarded as an analogue of the Ser140-Val141-Val142 segment of loop C, where the Ser residue has been allylated and Val141 has been (conservatively) substituted with another, structurally related, hydrophobic residue. The crystal structure of (I) renders a comparison with the backbone conformation of the AQP4 Ser140-Val142 segment possible. We have previously reported the crystal structure of a dipeptide analogue, Boc-Val-Val-OMe (Boc = tert-butoxycarbonyl), of the Val141-Val142 segment of AQP4 (Jacobsen et al., 2011 ).

Regardless of the relationship between (I) and loop C of AQP4, the presence of two non-proteinogenic residues in (I), i.e. the synthetic residue O-allyl-L-serine [Ser(All)] and the naturally occurring achiral α,α-disubstituted residue α-aminoisobutyric acid (Aib), makes the crystal structure of (I) potentially interesting per se. The Aib residue is found in a large number of antibiotic peptides produced by fungi known as peptaibiotics (Degenkolb & Brückner, 2008 ). It is a conformationally restricted residue that preferentially adopts a 3₁₀- or α-helical conformation (Ramachandran & Chandrasekaran, 1972 ; Marshall & Bosshard, 1972 ; Venkatraman et al., 2001 ; Aravinda et al., 2008 ). Compared to Aib, the properties of the Ser(All) residue have been less studied. As of 31 July 2011, only 170 compounds (including non-peptidic compounds) containing the O-allyl-L-serine fragment, (II), have been assigned a Chemical Abstracts Service Registry Number (American Chemical Society, 2008 ).

In many cases, the purpose of incorporating one or more Ser(All) residues in a peptide sequence has been to synthesize conformationally constrained peptides by ring-closing olefin metathesis (RCM) (Blackwell & Grubbs, 1998 ; Blackwell et al., 2001 ; Hanessian et al., 2006 ; Jacobsen et al., 2009; Yamagata et al., 2011 ). The structural and pharmacological effects of RCM in peptides have recently been reviewed (Jacobsen et al., 2010 ). A small number of crystal structures have been obtained of the resulting cyclic peptides or hydrogenated versions thereof (Blackwell & Grubbs, 1998; Hanessian et al., 2006; Boal et al., 2007 ; Abell et al., 2009 ; Yamagata et al., 2011). Perhaps because the properties of the cyclic peptides obtained after RCM have constituted the primary focus of several of the studies for which Ser(All)-containing peptides have been synthesized, only a single crystal structure, as far as we have been able to establish, has been reported of a peptide containing the O-allyl-L-serine residue (Boal et al., 2007). To determine the structural effect of i → i+3 side-chain-to-side-chain RCM in the context of a predominantly 3₁₀-helical peptide, Boal et al. (2007) determined the crystal structure of an Aib-rich octapeptide, Boc-Aib-Aib-Aib-Ser(All)-Aib-Aib-Ser(All)-Aib-OMe, (III), before and after RCM. Similarly to (I), the O-allyl-L-serine residue in (III) is succeeded by an Aib residue.

So far, no crystal structures of peptides containing the closely related residues O-allyl-L-threonine or S-allyl-L-cysteine have been reported.

A turn is defined as a segment of a peptide which reverses the direction of the backbone (Venkatachalam, 1968 ; Rose et al., 1985 ). A β-turn is a turn comprising four residues which may, or may not, be stabilized by an intramolecular i → i+3 hydrogen bond (Venkatachalam, 1968; Lewis et al., 1973 ; Richardson, 1981 ; Rose et al., 1985; Hutchinson & Thornton, 1994 ; Guruprasad & Rajkumar, 2000 ). The backbone of (I) changes direction by approximately 180° from the quaternary carbon (C1) of the Boc group to the C^α-atom (C16) of the Val residue, thus constituting a β-turn (Fig. 1a). The distance between the two C atoms is 5.908 (5) Å. In contrast to most β-turn subtypes, which feature an i → i+3 intramolecular hydrogen bond, (I) does not form any intramolecular hydrogen bonds. The H⋯O distance between the carbonyl O atom of the Boc group and the NH group of the Val residue is, however, relatively short at 3.34 Å [N⋯O = 3.898 (3) Å]. As a result of the turn, the shape of the peptide may be characterized as an (open) disc with a protruding Ser(All) side chain.

It is well established that Aib can promote/stabilize helical conformations when incorporated in peptides (Burgess & Leach, 1973 ; Karle & Balaram, 1990 ; Marshall et al., 1990 ). However, no such effect is evident in the crystal structure of (I). Instead the two chiral residues adopt polyproline II (P_II) conformations, with (φ, ψ) of Ser(All) and Val being [−59.0 (4), 159.2 (3)°] and [−70.3 (3), 143.5 (3)°], respectively. The P_II conformation is believed to be an important local conformation of `unfolded' peptides (Shi et al., 2006 ; Makowska et al., 2006 ). Because it lacks a stereogenic centre, the Aib residue can adopt left- or right-handed helical conformations with equal probability when incorporated in achiral peptides. However, when it is involved in intramolecular hydrogen bonding in a helical peptide containing L-amino acids it preferentially adopts right-handed helical conformations (Aravinda et al., 2008). The central Aib residue in the nonhelical peptide (I) adopts a left-handed 3₁₀-helical (3_10L) conformation, with (φ, ψ) angles of [58.7 (4), 33.1 (4)°]. This conformation allows the formation of favourable intramolecular hydrophobic and van der Waals interactions between the tert-butyl and isopropyl groups and between the Ser(All) side chain and the Aib side chains. The backbone conformation of (I) closely resembles the conformations of several other fully protected tripeptides with a centrally placed Aib residue, e.g. Boc-L-Phe-Aib-L-Ile-OMe (Das et al., 2005 ), Boc-L-Ile-Aib-L-Val-OMe (Dutt et al., 2007 ), Boc-L-Ala-Aib-L-Val-OMe (Maji et al., 2004 ), Boc-L-Ala-Aib-L-Ile-OMe (Maji et al., 2004) and Boc-L-Ala-Aib-L-Ala-OMe, (IV) (Bosch et al., 1984 ). (IV) crystallizes in the space group P2₁ and forms a distorted β-turn with a P_II–3_10L–P_II backbone conformation very similar to that of (I) (Fig. 1b). Recent conformational studies of (IV) by NMR, IR, vibrational circular dichroism (VCD) and electronic circular dichroism (ECD) spectroscopy, however, suggest that the structure of (IV) is more complex in aqueous solution than in the solid state (Schweitzer-Stenner et al., 2007 ). In contrast to the crystal structure, the population of Aib residues adopting a right-handed 3₁₀-helical conformation appears to be greater than the population of Aibs adopting a left-handed conformation, but it is difficult to predict whether this would also be the case for (I) in aqueous solution.

Based on the observed (φ, ψ) angles of the Ser(All), Ala (residue i+1) and Aib (residue i+2), the structures of (I) and (IV) do not fall naturally into any of the standard β-turn classes (Richardson, 1981; Rose et al., 1985; Hutchinson & Thornton, 1994; Guruprasad & Rajkumar, 2000). The most similar type, the type-II β-turn, has dihedral angles (φ_i+1, ψ_i+1) = (−60, 120°) and (φ_i+2, ψ_i+2) = (80, 0°) (Guruprasad & Rajkumar, 2000).

Compared with the CO(Pro139)-Ser140-Val141-Val142 segment of rAQP4, (I) adopts a completely different overall conformation, as well as at the level of the individual residues (Table 1). While the Ser(All) and Aib residues of (I) adopt P_II and left-handed 3₁₀-helical conformations, respectively, Ser140 of rAQP4 contribute to forming a short right-handed 3₁₀-helix. In contrast, despite very different individual torsion angles, the overall backbone conformation of the CO(Pro139)-Ser140-Val141-Val142 segment of human AQP4 (hAQP4) [Protein Data Bank (PDB) code 3GD8; Ho et al., 2009 ] (Fig. 1c) is quite similar to that of (I). One notable difference is that the central Ser140-Val141 peptide bond is flipped; (I) may be characterized as a distorted type-II β-turn, while the hAQP4 fragment has a distorted type-I β-turn conformation.

The side chain of the Ser(All) residue adopts a gauche conformation relative to both backbone bonds [N1—C6—C7—O3 = 69.5 (3)° and C11—C6—C7—O3 = −51.9 (3)°]. The same conformation is observed for one of the Ser(All) residues in the crystal structure of the octapeptide (III) (Boal et al., 2007), which may be stabilized by favourable σ_Cα—H→σ*_C—O and σ_Cβ—H→σ*_C—N hyperconjugative interactions. On the other hand, the C^β—O bond in the side chain of the second Ser(All) in (III) is positioned anti relative to the CO—C^α bond and gauche relative to the C^α—N bond, suggesting that the energy difference between the two side-chain conformers could be small. Going further out in the side chain, the H atoms of the two CH₂ groups are almost eclipsed in all three cases. At first sight, this would appear to be an unfavourable conformation, but it should be noted that this arrangement reduces the steric repulsion between the C—H groups and the oxygen lone pairs and furthermore allows some overlap between the four σ_C—H orbitals and the two σ*_C—O orbitals. Obviously, it is difficult, based on only three observations in two crystal structures, to draw any firm conclusions about the conformational preferences of the Ser(All) side chain without recourse to ab initio or density functional theory (DFT) calculations, which is beyond the scope of the current study.

The crystal packing of (I) is divided into one-molecule-thick layers along the c axis, each layer having a B–A–B′ composition, where A represents a hydrophilic core, and B and B′ are two different sets of hydrophobic groups (Fig. 2). In part A the peptide backbones form two intermolecular hydrogen bonds that generate one C(11) head-to-tail chain along the ab diagonal and one C(5) chain along the b axis (Fig. 3); for graph-set notation, see Etter et al. (1990 ). Notably, the N3—H3 donor, which fails to form an intramolecular hydrogen bond, is only involved in a very weak interaction (Table 2). The hydrophobic part B of each molecular layer comprises the Aib side chains and terminal Ser(All) olefin/vinyl groups, while part B′ has contributions from the isopropyl groups of the Val residues together with the tert-butyl groups. The overall B–A–B′⋯B′–A–B⋯B–A–B′ stacking thus incorporates two distinct types of hydrophobic interfaces B⋯B and B′⋯B′ parallel to the ab plane, an arrangement that allows the vinyl groups to enjoy favourable π–π interactions (Hunter & Sanders, 1990 ) with each other. The internuclear distance between the partially positively charged terminal H atoms and the two C atoms in the π system is on the order of 3.7–4.1 Å.

Figure 1
(a) The asymmetric unit of (I)

, with the atom numbering indicated. Displacement ellipsoids are drawn at the 50% probability level and H atoms are shown as spheres of arbitrary size. Bond lengths are normal, except that the O3—C8 and C9—C10 bonds in the allyl group are comparatively short at 1.395 (5) and 1.274 (7) Å, respectively. (b) The structure of Boc-L-Ala-Aib-L-Ala-OMe, (IV) [Cambridge Structural Database (Allen, 2002

) refcode COLSOL; Bosch et al., 1984

]. (c) The Pro139-Val142 segment of hAQP4 (PDB code 3GD8; Ho et al., 2009

Figure 2
The unit cell and crystal packing of (I)

, viewed along the b axis. H atoms bonded to C atoms have been omitted for clarity and hydrogen bonds are shown as dotted lines. The structure is divided into layers, limited by grey dashed lines, where each layer has a B (red in the electronic version of the paper) – A (blue) – B′ (yellow) composition. Hydrogen bonds in the hydrophilic core A are shown as dotted lines.

Figure 3
The hydrogen-bonding pattern in the ab plane as viewed along c* with the directions of the a and b axes as well as the ab diagonal (dashed line) indicated. The acceptor atoms are O7ⁱ and O5ⁱⁱ [symmetry codes: (i) x − $[{1\over 2}]$ , y − $[{1\over 2}]$ , z; (ii) x, y − 1, z]. A single long N3—H3⋯O6ⁱⁱ contact (see Table 2

; orange in the electronic version of the paper) is indicated with an arrow. [Also in the electronic version of the paper, the tert-butyl group, the Ser(All) side chain and the Val chain are depicted as black, orange and violet spheres, respectively.]

Experimental

The N-(tert-butoxycarbonyl)-O-allyl-L-serine building block was synthesized in an analogous manner to N-(tert-butoxycarbonyl)-O-benzyl-L-serine (Sugano & Miyoshi, 1976 ) by double deprotonation of N-(tert-butoxycarbonyl)-L-serine with NaH in dimethylformamide, followed by alkylation with allyl bromide (Jacobsen et al., 2009). The title compound, (I), was synthesized by standard solution-phase peptide coupling of N-(tert-butoxycarbonyl)-O-allyl-L-serine and α-aminoisobutyryl-L-valine methyl ester, which was generated in situ from α-aminoisobutyryl-L-valine methyl ester trifluoroacetate by reaction with N,N-diisopropylethylamine. 1-Ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) hydrochloride was used as coupling reagent and 1.0 equivalent of 1-hydroxybenzotriazole (HOBt) was added to catalyse the reaction and suppress epimerization (Jacobsen et al., 2009). The crude product was recrystallized twice from ethyl acetate–hexane (4:1 v/v). About 5 mg of (I) was dissolved in 30 µl of ethyl acetate. Crystals appeared as water vapour diffused into the solution at room temperature.

Crystal data

C₂₁H₃₇N₃O₇
M_r = 443.54
Monoclinic, C 2
a = 19.753 (4) Å
b = 5.9369 (12) Å
c = 21.343 (5) Å
β = 101.271 (3)°
V = 2454.7 (9) Å³
Z = 4
Mo Kα radiation
μ = 0.09 mm⁻¹
T = 105 K
0.60 × 0.43 × 0.24 mm

Data collection

Bruker APEXII CCD diffractometer
Absorption correction: multi-scan (SADABS; Bruker, 2007 ) T_min = 0.839, T_max = 0.979
7153 measured reflections
2431 independent reflections
2078 reflections with I > 2σ(I)
R_int = 0.034

Refinement

R[F² > 2σ(F²)] = 0.042
wR(F²) = 0.107
S = 1.05
2431 reflections
280 parameters
1 restraint
H-atom parameters constrained
Δρ_max = 0.28 e Å⁻³
Δρ_min = −0.18 e Å⁻³

Table 2
Hydrogen-bond geometry (Å, °)

D—H⋯A	D—H	H⋯A	D⋯A	D—H⋯A
N1—H1⋯O7ⁱ	0.88	2.23	3.060 (3)	157
N2—H2⋯O5ⁱⁱ	0.88	2.04	2.900 (3)	164
N3—H3⋯O6ⁱⁱ	0.88	2.95	3.621 (3)	135
Symmetry codes: (i) $[x-{\script{1\over 2}}, y-{\script{1\over 2}}, z]$ ; (ii) x, y-1, z.

Table 1
Main torsion angles (°) in the crystal structure of (I) and for the Ser-Val-Val segments of three AQP4 structures from the PDB (identifier code given)

Torsion angle^a	This work	2D57^b	2ZZ9^c	3GD8^d
φ₁	−59.0 (4)	−139.4	−117.9	−64.2
ψ₁	159.2 (3)	−7.8	5.6	−21.4
φ₂	58.7 (4)	−59.0	−67.9	−118.2
ψ₂	33.1 (4)	−32.5	−18.8	−1.6
φ₃	−70.3 (3)	−30.6	−21.7	−50.9
ψ₃	143.5 (3)	−35.7	−41.7	−44.6
Notes: (a) For (I), with reference to Fig. 1, the listed torsion angles are: φ₁ = C5—N1—C6—C11, ψ₁ = N1—C6—C11—N2, φ₂ = C11—N2—C12—C15, ψ₂ = N2—C12—C15—N3, φ₃ = C15—N3—C16—C20 and ψ₃ = N3—C16—C20—O6; (b) Hiroaki et al. (2006); (c) Tani et al. (2009); (d) Ho et al. (2009).

All H atoms were positioned with idealized geometry, with fixed N—H = 0.88 Å and C—H = 0.95 (sp²), 0.98 (methyl), 0.99 (methylene) or 1.00 Å (methine), while permitting free rotation for the amino groups. U_iso(H) values were set at 1.2U_eq of the carrier atom or at 1.5U_eq for methyl groups. In the absence of significant anomalous scattering effects, 1774 Friedel pairs were merged.

Data collection: APEX2 (Bruker, 2007); cell refinement: SAINT-Plus (Bruker, 2007); data reduction: SAINT-Plus; program(s) used to solve structure: SHELXS97 (Sheldrick, 2008 ); program(s) used to refine structure: SHELXL97 (Sheldrick, 2008); molecular graphics: SHELXTL (Sheldrick, 2008); software used to prepare material for publication: SHELXTL.

Supporting information

Crystal structure: contains datablocks I, global. DOI: 10.1107/S0108270111029647/sf3155sup1.cif

Structure factors: contains datablock I. DOI: 10.1107/S0108270111029647/sf3155Isup2.hkl

Comment top

The title peptide, (I), was prepared as part of an ongoing effort (Jacobsen et al., 2009) to synthesize analogues of the Pro138–Gly144 segment of the extracellular loop C of the water channel aquaporin-4 (AQP4) [protein?] (Hasegawa et al., 1994; Jung et al., 1994; Hiroaki et al., 2006), which has emerged as an important target for the treatment of brain oedema (Nielsen et al., 1997; Manley et al., 2000; Amiry-Moghaddam et al., 2003; Amiry-Moghaddam & Ottersen, 2003). The residues Pro139 and Val142 are thought to mediate adhesive interactions between AQP4 molecules in contiguous cell membranes (Hiroaki et al., 2006; Engel et al., 2008; Tani et al., 2009). The electron diffraction structure of rat AQP4 (rAQP4) revealed that the segment Ser140–Gly144 forms a short 3₁₀-helix [Protein Data Bank (PDB) code 2D57, Hiroaki et al., 2006; PDB code 2ZZ9, Tani et al., 2009]. We believe that compounds structurally mimicking a loop-C segment containing at least one of the residues mediating adhesion can potentially have affinity for AQP4 and serve as lead compounds for the development of selective AQP4 ligands and, eventually, AQP4 inhibitors. (I) may be regarded as an analogue of the Ser140–Val141–Val142 segment of loop C, where the Ser residue has been allylated and Val141 has been (conservatively) substituted with another, structurally related, hydrophobic residue. The crystal structure of (I) renders a comparison with the backbone conformation of the AQP4 Ser140–Val142 segment possible. We have previously reported the crystal structure of a dipeptide analogue, Boc–Val–Val–OMe, of the Val141–Val142 segment of AQP4 (Jacobsen et al., 2011).

Regardless of the relationship between (I) and loop C of AQP4, the presence of two non-proteinogenic residues in (I), i.e. the synthetic residue O-allyl-L-serine [Ser(All)] and the naturally occurring achiral α,α-disubstituted residue α-aminoisobutyric acid (Aib), makes the crystal structure of (I) potentially interesting per se. The Aib residue is found in a large number of antibiotic peptides produced by fungi known as peptaibiotics (Degenkolb & Brückner, 2008). It is a conformationally restricted residue that preferentially adopts a 3₁₀– or α-helical conformation (Ramachandran & Chandrasekaran, 1972; Marshall & Bosshard, 1972; Venkatraman et al., 2001; Aravinda et al., 2008). Compared to Aib, the properties of the Ser(All) residue have been less studied. As of 27 May 2011 only 162 compounds (including non-peptidic compounds) containing the O-allyl-L-serine fragment, (II), have been indexed in the Chemical Abstracts database.

In many cases, the purpose of incorporating one or more Ser(All) residues in a peptide sequence has been to synthesize conformationally constrained peptides by ring-closing olefin metathesis (RCM) (Blackwell & Grubbs, 1998; Blackwell et al., 2001; Hanessian et al., 2006; Jacobsen et al., 2009; Yamagata et al., 2011). The structural and pharmacological effects of RCM in peptides have recently been reviewed (Jacobsen et al., 2010). A small number of crystal structures have been obtained of the resulting cyclic peptides or hydrogenated versions thereof (Blackwell & Grubbs, 1998; Hanessian et al., 2006; Boal et al., 2007; Abell et al., 2009; Yamagata et al., 2011). Perhaps because the properties of the cyclic peptides obtained after RCM have constituted the primary focus of several of the studies for which Ser(All)-containing peptides have been synthesized, only a single crystal structure, as far as we have been able to establish, has been reported of a peptide containing the O-allyl-L-serine residue (Boal et al., 2007). To determine the structural effect of i → i+3 side-chain-to-side-chain RCM in the context of a predominantly 3₁₀-helical peptide, Boal et al. (2007) determined the crystal structure of an Aib-rich octapeptide, Boc–Aib–Aib–Aib–Ser(All)–Aib–Aib–Ser(All)–Aib–OMe, (II), before and after RCM. Similarly to (I), the O-allyl-L-serine residue in (II) is succeeded by an Aib residue.

So far, no crystal structures of peptides containing the closely related residues O-allyl-L-threonine or S-allyl-L-cysteine have been reported.

A turn is defined as a segment of a peptide which reverses the direction of the backbone (Venkatachalam, 1968; Rose et al., 1985). A β-turn is a turn comprising four residues which may, or may not, be stabilized by an intramolecular i → i+3 hydrogen bond (Venkatachalam, 1968; Lewis et al., 1973; Richardson, 1981; Rose et al., 1985; Hutchinson & Thornton, 1994; Guruprasad & Rajkumar, 2000). The backbone of (I) changes direction by approximately 180° from the quaternary carbon of the tert-butoxycarbonyl (Boc) group to the C^α-atom of the Val residue, thus constituting a β-turn (Fig. 1a). The distance between the two carbon atoms is 5.908 (5) Å. In contrast to most β-turn subtypes, which feature an i → i+3 intramolecular hydrogen bond, (I) does not form any intramolecular hdyrogen bonds. The H···O distance between the carbonyl oxygen of the Boc group and the NH of the Val residue is, however, relatively short at 3.34 Å [N···O is 3.898 (3) Å]. As a result of the turn, the shape of the peptide may be characterized as an (open) disc with a protruding Ser(All) side chain.

It is well established that Aib can promote/stabilize helical conformations when incorporated in peptides (Burgess & Leach, 1973; Karle & Balaram, 1990; Marshall et al., 1990). However, no such effect is evident in the crystal structure of (I). Instead the two chiral residues adopt polyproline II (P_II) conformations, with (ϕ, ψ) of Ser(All) and Val being [-59.0 (4)°, 159.2 (3)°] and [-70.3 (3)°, 143.5 (3)°], respectively. The P_II conformation is believed to be an important local conformation of `unfolded' peptides (Shi et al., 2006; Makowska et al., 2006). Because it lacks a stereogenic centre the Aib residue can adopt left-handed or right-handed helical conformations with equal probability when incorporated in achiral peptides. However, when it is involved in intramolecular hydrogen bonding in a helical peptide containing L-amino acids it preferentially adopts right-handed helical conformations (Aravinda et al., 2008). The central Aib residue in the non-helical peptide (I) adopts a left-handed 3₁₀-helical (3₁₀_L) conformation, with (ϕ, ψ) angles [58.7 (4)°, 33.1 (4)°]. This conformation allows the formation of favourable intramolecular hydrophobic and van der Waals interactions between the tert-butyl and isopropyl groups and between the Ser(All) side chain and the Aib side chains. The backbone conformation of (I) closely resembles the conformations of several other fully protected tripeptides with a centrally placed Aib residue, e.g. Boc–L-Phe–Aib–L-Ile–OMe (Das et al., 2005), Boc–L-Ile–Aib–L-Val–OMe (Dutt et al., 2007), Boc–L-Ala–Aib–L-Val–OMe (Maji et al., 2004), Boc–L-Ala–Aib–L-Ile–OMe (Maji et al., 2004) and Boc–L-Ala–Aib–L-Ala–OMe, (III) (Bosch et al., 1984). (III) crystallizes in space group P2₁ and forms a distorted β-turn with a P_II-3₁₀_L-P_II backbone conformation very similar to (I) (Fig. 1b). Recent conformational studies of (III) by NMR, IR, VCD [vibrational circular dichroism?] and ECD [pls define] spectroscopy, however, suggest that the structure of (III) is more complex in aqueous solution than in the solid state (Schweitzer-Stenner et al., 2007). In contrast to the crystal structure, the population of Aib residues adopting a right-handed 3₁₀-helical conformation appears to be greater than the population of Aibs adopting a left-handed conformation, but it is difficult to predict whether this would also be the case for (I) in aqueous solution.

Based on the observed (ϕ, ψ) angles of the Ser(All)/Ala (residue i+1) and Aib (residue i+2) the structures of (I) and (III) do not fall naturally into any of the standard β-turn classes (Richardson, 1981; Rose et al., 1985; Hutchinson & Thornton, 1994; Guruprasad & Rajkumar, 2000). The most similar type, the type-II β-turn, has dihedral angles (ϕ_i+1,ψ_i+1) = (-60°, 120°) and (ϕ_i+2,ψ_i+2) = (80°, 0°) (Guruprasad & Rajkumar, 2000).

Compared with the CO(Pro139)–Ser140–Val141–Val142 segment of rAQP4 (I) adopts a completely different overall conformation, as well as at the level of the individual residues (Table 1). While the Ser(All) and Aib residues of (I) adopt P_II and left-handed 3₁₀-helical conformations, respectively, Ser140 of rAQP4 adopts a distorted right-handed 3₁₀-/α- helical conformation and the central Val residue a right-handed 3₁₀-helical conformation. In contrast, despite very different individual torsion angles, the overall backbone conformation of the CO(Pro139)–Ser140–Val141–Val142 segment of human AQP4 (hAQP4) (PDB code 3GD8, Ho et al., 2009) (Fig. 1c) is quite similar to that of (I). One notable difference is that the central Ser140–Val141 peptide bond is flipped; (I) may be characterized as a distorted type-II β-turn, while the hAQP4 fragment has a distorted type-I β-turn conformation.

The side chain of the Ser(All) residue adopts a gauche conformation relative to both backbone bonds [N1—C6—C7—O3 = 69.5 (3)°, C11—C6—C7—O3 = -51.9 (3)°]. The same conformation is observed for one of the Ser(All) residues in the crystal structure of the octapeptide (II) (Boal et al., 2007), which may be stabilized by favourable σ_C_α_-H→σ*_C—O and σ_C_β_-H→σ*_C—N hyperconjugative interactions. On the other hand, the C^β—O bond in the side chain of the second Ser(All) in (II) is positioned anti relative to the CO—C^α bond and gauche relative to the C^α—N bond, suggesting that the energy difference between the two side-chain conformers could be small. Going further out in the side chain, the H atoms of the two CH₂ groups are almost eclipsed in all three cases. At first sight, this would appear to be an unfavourable conformation, but it should be noted that this arrangement reduces the steric repulsion between the C—H groups and the oxygen lone pairs as well as allowing some overlap between the four σ_C—H orbitals and the two σ*_C—O orbitals. Obviously, it is difficult, based on only three observations in two crystal structures, to draw any firm conclusions about the conformational preferences of the Ser(All) side chain without recourse to ab initio or DFT calculations, which is beyond the scope of the current study.

The crystal packing of (I) is divided into one-molecule-thick layers along the c axis, each layer having a B–A–B' construction where A represents a hydrophilic core, and B and B' are two different sets of hydrophobic groups (Fig. 2). In part A the peptide backbones form two intermolecular hydrogen bonds that generate one C(11) head-to-tail chain along the ab diagonal and one C(5) chain along the b axis (Fig. 3). Notably, the N3—H3 donor, which fails to form an intramolecular hydrogen bond (see above), is only involved in a very weak interaction (Table 2). The hydrophobic part B of each molecular layer comprises the Aib side chains and terminal Ser(All) olefin/vinyl groups, while part B' has contributions from the isopropyl groups of the Val residues together with the tert-butyl groups. The overall B–A–B'···B'–A–B···B–A–B' stacking thus incorporates two distinct types of hydrophobic interfaces B···B and B'···B' parallel to the ab plane, an arrangement that allows the vinyl groups to enjoy favourable π–π interactions (Hunter & Sanders, 1990) with each other. The internuclear distance between the partially positively charged terminal protons and the two carbon atoms in the π system is on the order of 3.7–4.1 Å.

Related literature top

For related literature, see: Abell et al. (2009); Amiry-Moghaddam & Ottersen (2003); Amiry-Moghaddam, Otsuka, Hurn, Traystman, Haug, Froehner, Adams, Neely, Agre, Ottersen & Bhardwaj (2003); Aravinda et al. (2008); Blackwell & Grubbs (1998); Blackwell et al. (2001); Boal et al. (2007); Bosch et al. (1984); Burgess & Leach (1973); Das et al. (2005); Degenkolb & Brückner (2008); Dutt et al. (2007); Engel et al. (2008); Guruprasad & Rajkumar (2000); Hanessian et al. (2006); Hasegawa et al. (1994); Hiroaki et al. (2006); Ho et al. (2009); Hunter & Sanders (1990); Hutchinson & Thornton (1994); Jacobsen et al. (2009, 2010, 2011); Jung et al. (1994); Karle & Balaram (1990); Lewis et al. (1973); Maji et al. (2004); Makowska et al. (2006); Manley et al. (2000); Marshall & Bosshard (1972); Marshall et al. (1990); Nielsen et al. (1997); Ramachandran & Chandrasekaran (1972); Richardson (1981); Rose et al. (1985); Schweitzer-Stenner, Gonzales, Bourne, Feng & Marshall (2007); Shi et al. (2006); Sugano & Miyoshi (1976); Tani et al. (2009); Venkatachalam (1968); Venkatraman et al. (2001); Yamagata et al. (2011).

Experimental top

The N-tert-butoxycarbonyl-O-allyl-L-serine building block was synthesized in an analagous manner to N-tert-O-benzyl-L-serine (Sugano & Miyoshi, 1976) by double deprotonation of N-tert-butoxycarbonyl-L-serine with NaH in dimethylformamide, followed by alkylation with allyl bromide (Jacobsen et al., 2009). The title compound, (I), was synthesized by standard solution phase peptide coupling of N-tert-butoxycarbonyl-O-allyl-L-serine and α-aminoisobutyryl-L-valine methyl ester, which was generated in situ from α-aminoisobutyryl-L-valine methyl ester trifluoroacetate by reaction with N,N-diisopropylethylamine. 3-(3-Dimethylaminopropyl)-1-ethylcarbodiimide (EDC) was used as coupling reagent and 1.0 equivalent of 1-hydroxybenzotriazole (HOBt) was added to catalyse the reaction and suppress epimerization (Jacobsen et al., 2009). The crude product was recrystallized twice from ethyl acetate–hexane (4:1 v/v). About 5 mg of (I) was dissolved in 30 µl of ethyl acetate. Crystals appeared as water vapour diffused into the solution at room temperature.

Computing details top

Data collection: APEX2 (Bruker, 2007); cell refinement: SAINT-Plus (Bruker, 2007); data reduction: SAINT-Plus (Bruker, 2007); program(s) used to solve structure: SHELXS97 (Sheldrick, 2008); program(s) used to refine structure: SHELXL97 (Sheldrick, 2008); molecular graphics: SHELXTL (Sheldrick, 2008); software used to prepare material for publication: SHELXTL (Sheldrick, 2008).

Figures top

	Fig. 1. (a) The asymmetric unit of (I), with the atom numbering indicated. Displacement ellipsoids are drawn at the 50% probability level and H atoms are spheres of arbitrary size. Bond lengths are normal, except that the O3—C8 and C9—10 bonds in the allyl group are comparatively short at 1.395 (5) and 1.274 (7) Å, respectively. (b) The structure of Boc–L-Ala–Aib–L-Ala–OMe, (III) (CSD refcode COLSOL; Bosch et al., 1984). (c) The Pro139–Val142 segment of hAQP4 (PDB code 3GD8; Ho et al.., 2009).
	Fig. 2. The unit cell and crystal packing of (I), viewed along the b axis. H atoms bonded to C atoms have been omitted for clarity and hydrogen bonds are shown as dotted lines. The structure is divided into layers, limited by grey dashed lines, where each layer has a B (red in the electronic version of the paper) – A (blue) – B' (yellow) composition. Hydrogen bonds in the hydrophiliic core A are shown as dotted lines.
	Fig. 3. The hydrogen-bonding pattern in the ab plane as viewed along c* (axis directions are given top left), the acceptors are O7'(x - 1/2, y - 1/2, z) and O5''(x, y - 1, z). A single long N3—H3···O6''(x, y - 1, z) contact (see Table 2) is shown with an arrow (orange in the electronic version of the paper). [The tert-butyl group, the Ser(All) side chain and the Val chain are depicted as black, orange and violet spheres, respectively.]

(6S,12S)-methyl 6-(allyloxymethyl)-12-isopropyl-2,2,9,9-tetramethyl-4,7,10-trioxo-3-oxa- 5,8,11-triazatridecan-13-oate top

Crystal data top

C₂₁H₃₇N₃O₇	F(000) = 960
M_r = 443.54	D_x = 1.200 Mg m⁻³
Monoclinic, C2	Mo Kα radiation, λ = 0.71073 Å
Hall symbol: C 2y	Cell parameters from 4112 reflections
a = 19.753 (4) Å	θ = 2.0–25.2°
b = 5.9369 (12) Å	µ = 0.09 mm⁻¹
c = 21.343 (5) Å	T = 105 K
β = 101.271 (3)°	Block, colourless
V = 2454.7 (9) Å³	0.60 × 0.43 × 0.24 mm
Z = 4

Data collection top

Bruker APEXII CCD diffractometer	2431 independent reflections
Radiation source: fine-focus sealed tube	2078 reflections with I > 2σ(I)
Graphite monochromator	R_int = 0.034
Detector resolution: 8.3 pixels mm^-1	θ_max = 25.2°, θ_min = 2.0°
Sets of exposures each taken over 0.5° ω rotation scans	h = −23→23
Absorption correction: multi-scan (SADABS; Bruker, 2007)	k = −7→6
T_min = 0.839, T_max = 0.979	l = −25→25
7153 measured reflections

Refinement top

Refinement on F²	Primary atom site location: structure-invariant direct methods
Least-squares matrix: full	Secondary atom site location: difference Fourier map
R[F² > 2σ(F²)] = 0.042	Hydrogen site location: inferred from neighbouring sites
wR(F²) = 0.107	H-atom parameters constrained
S = 1.05	w = 1/[σ²(F_o²) + (0.0599P)² + 0.5885P] where P = (F_o² + 2F_c²)/3
2431 reflections	(Δ/σ)_max < 0.001
280 parameters	Δρ_max = 0.28 e Å⁻³
1 restraint	Δρ_min = −0.18 e Å⁻³

Crystal data top

C₂₁H₃₇N₃O₇	V = 2454.7 (9) Å³
M_r = 443.54	Z = 4
Monoclinic, C2	Mo Kα radiation
a = 19.753 (4) Å	µ = 0.09 mm⁻¹
b = 5.9369 (12) Å	T = 105 K
c = 21.343 (5) Å	0.60 × 0.43 × 0.24 mm
β = 101.271 (3)°

Data collection top

Bruker APEXII CCD diffractometer	2431 independent reflections
Absorption correction: multi-scan (SADABS; Bruker, 2007)	2078 reflections with I > 2σ(I)
T_min = 0.839, T_max = 0.979	R_int = 0.034
7153 measured reflections

Refinement top

R[F² > 2σ(F²)] = 0.042	1 restraint
wR(F²) = 0.107	H-atom parameters constrained
S = 1.05	Δρ_max = 0.28 e Å⁻³
2431 reflections	Δρ_min = −0.18 e Å⁻³
280 parameters

Special details top

Geometry. All e.s.d.'s (except the e.s.d. in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell e.s.d.'s are taken into account individually in the estimation of e.s.d.'s in distances, angles and torsion angles; correlations between e.s.d.'s in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell e.s.d.'s is used for estimating e.s.d.'s involving l.s. planes.

Refinement. Refinement of F² against ALL reflections. The weighted R-factor wR and goodness of fit S are based on F², conventional R-factors R are based on F, with F set to zero for negative F². The threshold expression of F² > σ(F²) is used only for calculating R-factors(gt) etc. and is not relevant to the choice of reflections for refinement. R-factors based on F² are statistically about twice as large as those based on F, and R- factors based on ALL data will be even larger.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq
O1	0.33517 (11)	0.5968 (4)	0.85725 (10)	0.0333 (6)
O2	0.44157 (11)	0.4979 (4)	0.83790 (11)	0.0394 (6)
O3	0.28565 (12)	0.4215 (5)	0.63407 (12)	0.0442 (6)
O4	0.39446 (11)	0.7423 (4)	0.70273 (11)	0.0337 (6)
O5	0.52379 (12)	1.0591 (4)	0.64884 (11)	0.0350 (6)
O6	0.65077 (11)	1.3159 (4)	0.76237 (11)	0.0304 (5)
O7	0.68519 (11)	0.9710 (4)	0.73897 (11)	0.0327 (5)
N1	0.34194 (13)	0.4083 (5)	0.76931 (13)	0.0306 (6)
H1	0.2972	0.3863	0.7650	0.037*
N2	0.46616 (12)	0.4990 (4)	0.66585 (11)	0.0262 (6)
H2	0.4832	0.3616	0.6686	0.031*
N3	0.54918 (13)	0.8264 (5)	0.73300 (12)	0.0292 (6)
H3	0.5500	0.6881	0.7479	0.035*
C1	0.36277 (18)	0.7222 (7)	0.91624 (16)	0.0366 (8)
C2	0.4062 (2)	0.9196 (8)	0.9025 (2)	0.0647 (13)
H2A	0.3788	1.0155	0.8697	0.097*
H2B	0.4468	0.8637	0.8873	0.097*
H2C	0.4211	1.0072	0.9417	0.097*
C3	0.4008 (2)	0.5632 (9)	0.96604 (18)	0.0591 (12)
H3A	0.3700	0.4400	0.9728	0.089*
H3B	0.4161	0.6447	1.0062	0.089*
H3C	0.4410	0.5014	0.9514	0.089*
C4	0.29719 (19)	0.8059 (7)	0.93627 (17)	0.0439 (9)
H4A	0.2725	0.9081	0.9036	0.066*
H4B	0.3094	0.8861	0.9771	0.066*
H4C	0.2676	0.6772	0.9411	0.066*
C5	0.37883 (17)	0.5026 (6)	0.82265 (15)	0.0330 (8)
C6	0.37840 (17)	0.3440 (5)	0.71910 (15)	0.0297 (7)
H6	0.4144	0.2297	0.7364	0.036*
C7	0.32881 (18)	0.2429 (6)	0.66324 (16)	0.0367 (8)
H7A	0.3544	0.1759	0.6323	0.044*
H7B	0.3007	0.1236	0.6782	0.044*
C8	0.2247 (2)	0.3497 (8)	0.5945 (2)	0.0550 (11)
H8A	0.1949	0.2753	0.6206	0.066*
H8B	0.2356	0.2383	0.5635	0.066*
C9	0.1870 (2)	0.5445 (9)	0.5594 (2)	0.0644 (12)
H9	0.1409	0.5182	0.5376	0.077*
C10	0.2109 (3)	0.7425 (10)	0.5560 (2)	0.0691 (13)
H10A	0.2567	0.7768	0.5771	0.083*
H10B	0.1829	0.8559	0.5325	0.083*
C11	0.41346 (16)	0.5494 (6)	0.69608 (15)	0.0283 (7)
C12	0.49492 (16)	0.6677 (6)	0.62899 (14)	0.0272 (7)
C13	0.44078 (17)	0.7463 (7)	0.57211 (15)	0.0352 (8)
H13A	0.4234	0.6164	0.5454	0.053*
H13B	0.4617	0.8545	0.5469	0.053*
H13C	0.4025	0.8184	0.5875	0.053*
C14	0.55604 (16)	0.5609 (6)	0.60572 (15)	0.0310 (7)
H14A	0.5400	0.4310	0.5785	0.047*
H14B	0.5906	0.5113	0.6426	0.047*
H14C	0.5768	0.6720	0.5812	0.047*
C15	0.52233 (16)	0.8679 (5)	0.67126 (15)	0.0277 (7)
C16	0.57700 (16)	1.0118 (6)	0.77521 (15)	0.0304 (7)
H16	0.5429	1.1381	0.7686	0.036*
C17	0.58824 (17)	0.9380 (6)	0.84580 (15)	0.0307 (7)
H17	0.5463	0.8514	0.8510	0.037*
C18	0.59266 (18)	1.1425 (6)	0.88992 (16)	0.0368 (8)
H18A	0.5523	1.2392	0.8760	0.055*
H18B	0.6348	1.2275	0.8882	0.055*
H18C	0.5937	1.0920	0.9338	0.055*
C19	0.64998 (19)	0.7809 (6)	0.86562 (16)	0.0381 (8)
H19A	0.6455	0.6517	0.8365	0.057*
H19B	0.6514	0.7277	0.9093	0.057*
H19C	0.6927	0.8625	0.8637	0.057*
C20	0.64360 (16)	1.0935 (6)	0.75654 (14)	0.0273 (7)
C21	0.71266 (17)	1.4073 (6)	0.74431 (17)	0.0361 (8)
H21A	0.7137	1.5710	0.7503	0.054*
H21B	0.7123	1.3722	0.6994	0.054*
H21C	0.7536	1.3401	0.7712	0.054*

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
O1	0.0292 (12)	0.0418 (14)	0.0290 (12)	0.0025 (11)	0.0061 (10)	−0.0031 (11)
O2	0.0287 (12)	0.0455 (16)	0.0432 (13)	0.0027 (12)	0.0053 (11)	−0.0063 (12)
O3	0.0347 (13)	0.0480 (16)	0.0472 (15)	−0.0057 (13)	0.0016 (11)	−0.0096 (13)
O4	0.0330 (12)	0.0306 (14)	0.0392 (13)	0.0011 (11)	0.0113 (10)	−0.0019 (11)
O5	0.0428 (13)	0.0268 (12)	0.0369 (13)	0.0024 (11)	0.0115 (11)	0.0034 (11)
O6	0.0300 (11)	0.0227 (12)	0.0405 (13)	−0.0028 (9)	0.0117 (10)	−0.0006 (10)
O7	0.0321 (12)	0.0258 (12)	0.0414 (13)	−0.0014 (10)	0.0098 (10)	−0.0012 (11)
N1	0.0244 (13)	0.0370 (16)	0.0324 (15)	−0.0044 (13)	0.0103 (12)	−0.0016 (13)
N2	0.0291 (13)	0.0203 (14)	0.0302 (13)	−0.0007 (12)	0.0081 (11)	−0.0001 (12)
N3	0.0311 (14)	0.0221 (14)	0.0324 (14)	−0.0051 (12)	0.0012 (12)	0.0030 (12)
C1	0.0342 (18)	0.041 (2)	0.0342 (18)	−0.0001 (16)	0.0053 (15)	−0.0050 (17)
C2	0.063 (3)	0.057 (3)	0.084 (3)	−0.019 (2)	0.038 (2)	−0.031 (3)
C3	0.061 (3)	0.074 (3)	0.036 (2)	0.025 (3)	−0.0056 (19)	−0.007 (2)
C4	0.040 (2)	0.055 (2)	0.0363 (19)	0.0088 (18)	0.0070 (16)	−0.0050 (19)
C5	0.0346 (18)	0.0303 (19)	0.0357 (18)	0.0015 (16)	0.0111 (16)	0.0044 (16)
C6	0.0299 (16)	0.0260 (17)	0.0349 (18)	−0.0016 (14)	0.0108 (14)	−0.0030 (15)
C7	0.0355 (18)	0.036 (2)	0.0419 (19)	−0.0033 (17)	0.0150 (16)	−0.0055 (17)
C8	0.059 (3)	0.051 (3)	0.051 (2)	−0.015 (2)	0.000 (2)	−0.001 (2)
C9	0.058 (3)	0.060 (3)	0.066 (3)	−0.019 (2)	−0.009 (2)	−0.003 (3)
C10	0.059 (3)	0.064 (3)	0.080 (3)	0.006 (3)	0.005 (3)	−0.010 (3)
C11	0.0276 (16)	0.0277 (18)	0.0288 (16)	0.0012 (15)	0.0036 (14)	−0.0040 (15)
C12	0.0272 (16)	0.0291 (17)	0.0254 (15)	0.0018 (14)	0.0052 (13)	0.0017 (14)
C13	0.0358 (18)	0.038 (2)	0.0299 (17)	0.0023 (16)	0.0028 (15)	−0.0024 (16)
C14	0.0333 (17)	0.0301 (17)	0.0315 (16)	0.0013 (15)	0.0107 (14)	0.0017 (15)
C15	0.0275 (16)	0.0258 (18)	0.0306 (17)	0.0003 (14)	0.0081 (14)	0.0032 (14)
C16	0.0279 (16)	0.0276 (18)	0.0353 (17)	−0.0001 (14)	0.0052 (14)	0.0009 (15)
C17	0.0304 (16)	0.0305 (18)	0.0317 (17)	−0.0044 (14)	0.0071 (14)	0.0007 (15)
C18	0.039 (2)	0.0350 (19)	0.0355 (18)	−0.0013 (16)	0.0058 (16)	−0.0026 (16)
C19	0.050 (2)	0.034 (2)	0.0298 (17)	0.0049 (17)	0.0041 (16)	0.0029 (16)
C20	0.0307 (17)	0.0230 (18)	0.0263 (16)	−0.0014 (14)	0.0010 (14)	−0.0003 (14)
C21	0.0361 (18)	0.0290 (18)	0.045 (2)	−0.0041 (16)	0.0121 (16)	0.0013 (16)

Geometric parameters (Å, º) top

O1—C5	1.360 (4)	C7—H7A	0.9900
O1—C1	1.473 (4)	C7—H7B	0.9900
O2—C5	1.219 (4)	C8—C9	1.495 (7)
O3—C8	1.395 (5)	C8—H8A	0.9900
O3—C7	1.425 (5)	C8—H8B	0.9900
O4—C11	1.222 (4)	C9—C10	1.274 (7)
O5—C15	1.234 (4)	C9—H9	0.9500
O6—C20	1.332 (4)	C10—H10A	0.9500
O6—C21	1.456 (4)	C10—H10B	0.9500
O7—C20	1.210 (4)	C12—C13	1.526 (5)
N1—C5	1.348 (4)	C12—C15	1.526 (5)
N1—C6	1.454 (4)	C12—C14	1.530 (4)
N1—H1	0.8800	C13—H13A	0.9800
N2—C11	1.361 (4)	C13—H13B	0.9800
N2—C12	1.456 (4)	C13—H13C	0.9800
N2—H2	0.8800	C14—H14A	0.9800
N3—C15	1.344 (4)	C14—H14B	0.9800
N3—C16	1.460 (4)	C14—H14C	0.9800
N3—H3	0.8800	C16—C20	1.526 (4)
C1—C3	1.508 (5)	C16—C17	1.543 (4)
C1—C2	1.514 (6)	C16—H16	1.0000
C1—C4	1.524 (5)	C17—C19	1.528 (5)
C2—H2A	0.9800	C17—C18	1.528 (5)
C2—H2B	0.9800	C17—H17	1.0000
C2—H2C	0.9800	C18—H18A	0.9800
C3—H3A	0.9800	C18—H18B	0.9800
C3—H3B	0.9800	C18—H18C	0.9800
C3—H3C	0.9800	C19—H19A	0.9800
C4—H4A	0.9800	C19—H19B	0.9800
C4—H4B	0.9800	C19—H19C	0.9800
C4—H4C	0.9800	C21—H21A	0.9800
C6—C7	1.512 (5)	C21—H21B	0.9800
C6—C11	1.530 (5)	C21—H21C	0.9800
C6—H6	1.0000

C5—O1—C1	120.3 (2)	C9—C10—H10A	120.0
C8—O3—C7	114.1 (3)	C9—C10—H10B	120.0
C20—O6—C21	115.1 (3)	H10A—C10—H10B	120.0
C5—N1—C6	117.9 (3)	O4—C11—N2	122.8 (3)
C5—N1—H1	121.1	O4—C11—C6	122.8 (3)
C6—N1—H1	121.1	N2—C11—C6	114.4 (3)
C11—N2—C12	121.4 (3)	N2—C12—C13	110.7 (3)
C11—N2—H2	119.3	N2—C12—C15	110.3 (2)
C12—N2—H2	119.3	C13—C12—C15	110.2 (3)
C15—N3—C16	119.7 (3)	N2—C12—C14	107.8 (3)
C15—N3—H3	120.1	C13—C12—C14	110.1 (2)
C16—N3—H3	120.1	C15—C12—C14	107.7 (3)
O1—C1—C3	109.6 (3)	C12—C13—H13A	109.5
O1—C1—C2	110.8 (3)	C12—C13—H13B	109.5
C3—C1—C2	113.5 (4)	H13A—C13—H13B	109.5
O1—C1—C4	102.2 (3)	C12—C13—H13C	109.5
C3—C1—C4	109.9 (3)	H13A—C13—H13C	109.5
C2—C1—C4	110.3 (3)	H13B—C13—H13C	109.5
C1—C2—H2A	109.5	C12—C14—H14A	109.5
C1—C2—H2B	109.5	C12—C14—H14B	109.5
H2A—C2—H2B	109.5	H14A—C14—H14B	109.5
C1—C2—H2C	109.5	C12—C14—H14C	109.5
H2A—C2—H2C	109.5	H14A—C14—H14C	109.5
H2B—C2—H2C	109.5	H14B—C14—H14C	109.5
C1—C3—H3A	109.5	O5—C15—N3	120.9 (3)
C1—C3—H3B	109.5	O5—C15—C12	121.3 (3)
H3A—C3—H3B	109.5	N3—C15—C12	117.6 (3)
C1—C3—H3C	109.5	N3—C16—C20	108.5 (3)
H3A—C3—H3C	109.5	N3—C16—C17	110.7 (3)
H3B—C3—H3C	109.5	C20—C16—C17	112.2 (3)
C1—C4—H4A	109.5	N3—C16—H16	108.4
C1—C4—H4B	109.5	C20—C16—H16	108.4
H4A—C4—H4B	109.5	C17—C16—H16	108.4
C1—C4—H4C	109.5	C19—C17—C18	111.6 (3)
H4A—C4—H4C	109.5	C19—C17—C16	113.5 (3)
H4B—C4—H4C	109.5	C18—C17—C16	110.9 (3)
O2—C5—N1	124.7 (3)	C19—C17—H17	106.8
O2—C5—O1	125.7 (3)	C18—C17—H17	106.8
N1—C5—O1	109.5 (3)	C16—C17—H17	106.8
N1—C6—C7	110.3 (3)	C17—C18—H18A	109.5
N1—C6—C11	110.4 (3)	C17—C18—H18B	109.5
C7—C6—C11	109.1 (3)	H18A—C18—H18B	109.5
N1—C6—H6	109.0	C17—C18—H18C	109.5
C7—C6—H6	109.0	H18A—C18—H18C	109.5
C11—C6—H6	109.0	H18B—C18—H18C	109.5
O3—C7—C6	106.8 (3)	C17—C19—H19A	109.5
O3—C7—H7A	110.4	C17—C19—H19B	109.5
C6—C7—H7A	110.4	H19A—C19—H19B	109.5
O3—C7—H7B	110.4	C17—C19—H19C	109.5
C6—C7—H7B	110.4	H19A—C19—H19C	109.5
H7A—C7—H7B	108.6	H19B—C19—H19C	109.5
O3—C8—C9	110.7 (3)	O7—C20—O6	124.0 (3)
O3—C8—H8A	109.5	O7—C20—C16	124.2 (3)
C9—C8—H8A	109.5	O6—C20—C16	111.8 (3)
O3—C8—H8B	109.5	O6—C21—H21A	109.5
C9—C8—H8B	109.5	O6—C21—H21B	109.5
H8A—C8—H8B	108.1	H21A—C21—H21B	109.5
C10—C9—C8	126.0 (4)	O6—C21—H21C	109.5
C10—C9—H9	117.0	H21A—C21—H21C	109.5
C8—C9—H9	117.0	H21B—C21—H21C	109.5

C5—O1—C1—C3	−66.4 (4)	C11—N2—C12—C14	176.0 (3)
C5—O1—C1—C2	59.6 (4)	C16—N3—C15—O5	3.5 (4)
C5—O1—C1—C4	177.1 (3)	C16—N3—C15—C12	179.1 (3)
C6—N1—C5—O2	−15.5 (5)	N2—C12—C15—O5	−151.3 (3)
C6—N1—C5—O1	166.4 (3)	C13—C12—C15—O5	−28.8 (4)
C1—O1—C5—O2	5.3 (5)	C14—C12—C15—O5	91.3 (3)
C1—O1—C5—N1	−176.6 (3)	N2—C12—C15—N3	33.1 (4)
C5—N1—C6—C7	−179.7 (3)	C13—C12—C15—N3	155.6 (3)
C5—N1—C6—C11	−59.0 (4)	C14—C12—C15—N3	−84.3 (3)
C8—O3—C7—C6	−161.8 (3)	C15—N3—C16—C20	−70.3 (3)
N1—C6—C7—O3	69.5 (3)	C15—N3—C16—C17	166.1 (3)
C11—C6—C7—O3	−51.9 (3)	N3—C16—C17—C19	73.3 (4)
C7—O3—C8—C9	−172.7 (3)	C20—C16—C17—C19	−48.2 (4)
O3—C8—C9—C10	11.7 (7)	N3—C16—C17—C18	−160.2 (3)
C12—N2—C11—O4	−11.7 (5)	C20—C16—C17—C18	78.4 (3)
C12—N2—C11—C6	166.4 (3)	C21—O6—C20—O7	1.5 (5)
N1—C6—C11—O4	−22.7 (4)	C21—O6—C20—C16	−179.0 (3)
C7—C6—C11—O4	98.7 (4)	N3—C16—C20—O7	−37.0 (4)
N1—C6—C11—N2	159.2 (3)	C17—C16—C20—O7	85.7 (4)
C7—C6—C11—N2	−79.4 (3)	N3—C16—C20—O6	143.5 (3)
C11—N2—C12—C13	−63.5 (4)	C17—C16—C20—O6	−93.8 (3)
C11—N2—C12—C15	58.7 (4)

Hydrogen-bond geometry (Å, º) top

D—H···A	D—H	H···A	D···A	D—H···A
N1—H1···O7ⁱ	0.88	2.23	3.060 (3)	157
N2—H2···O5ⁱⁱ	0.88	2.04	2.900 (3)	164
N3—H3···O6ⁱⁱ	0.88	2.95	3.621 (3)	135

Symmetry codes: (i) x−1/2, y−1/2, z; (ii) x, y−1, z.

Experimental details

Crystal data
Chemical formula	C₂₁H₃₇N₃O₇
M_r	443.54
Crystal system, space group	Monoclinic, C2
Temperature (K)	105
a, b, c (Å)	19.753 (4), 5.9369 (12), 21.343 (5)
β (°)	101.271 (3)
V (Å³)	2454.7 (9)
Z	4
Radiation type	Mo Kα
µ (mm⁻¹)	0.09
Crystal size (mm)	0.60 × 0.43 × 0.24

Data collection
Diffractometer	Bruker APEXII CCD diffractometer
Absorption correction	Multi-scan (SADABS; Bruker, 2007)
T_min, T_max	0.839, 0.979
No. of measured, independent and observed [I > 2σ(I)] reflections	7153, 2431, 2078
R_int	0.034
(sin θ/λ)_max (Å⁻¹)	0.599

Refinement
R[F² > 2σ(F²)], wR(F²), S	0.042, 0.107, 1.05
No. of reflections	2431
No. of parameters	280
No. of restraints	1
H-atom treatment	H-atom parameters constrained
Δρ_max, Δρ_min (e Å⁻³)	0.28, −0.18

Computer programs: APEX2 (Bruker, 2007), SAINT-Plus (Bruker, 2007), SHELXS97 (Sheldrick, 2008), SHELXL97 (Sheldrick, 2008), SHELXTL (Sheldrick, 2008).

Hydrogen-bond geometry (Å, º) top

D—H···A	D—H	H···A	D···A	D—H···A
N1—H1···O7ⁱ	0.88	2.23	3.060 (3)	156.8
N2—H2···O5ⁱⁱ	0.88	2.04	2.900 (3)	163.9
N3—H3···O6ⁱⁱ	0.88	2.95	3.621 (3)	134.5

Symmetry codes: (i) x−1/2, y−1/2, z; (ii) x, y−1, z.

Main torsion angles (°) in the crystal structures of (I) and for the Ser-Val-Val segments of three AQP4 structures from the PDB (identifier code given). top

Torsion angle^a	This work	2D57^b	2ZZ9^c	3GD8^d
ϕ₁	-59.0 (4)	-139.4	-117.9	-64.2
ψ₁	159.2 (3)	-7.8	5.6	-21.4
ϕ₂	58.7 (4)	-59.0	-67.9	-118.2
ψ₂	33.1 (4)	-32.5	-18.8	-1.6
ϕ₃	-70.3 (3)	-30.6	-21.7	-50.9
ψ₃	143.5 (3)	-35.7	-41.7	-44.6

Notes: (a) For (I), with reference to Fig. 1, the listed torsion angles are: ϕ₁ = C5—N1—C6—C11, ψ₁ = N1—C6—C11—N2, ϕ₂ = C11—N2—C12—C15, ψ₂ = N2—C12—C15—N3, ϕ₃ = C15—N3—C16—C20 and ψ₃ = N3—C16—C20—O6; (b) Hiroaki et al. (2006); (c) Tani et al. (2009); (d) Ho et al. (2009).

Footnotes

‡These authors contributed equally to this work.

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