セルローストリプロピオネート (CTP) の1本の分子鎖について, 1残基内および連続する残基間の非結合原子間反発エネルギーを考慮したパーチュアルボンド法により, コンフォーメーション解析を行なった。X線繊維図から, CTPの繊維周期は1. 508nmと計算され, 消滅則より分子鎖方向に3回らせん軸が存在する。このように分子軸方向に3回らせん軸をもつセルローストリプロピオネートの構造は, 他のセルローストリエステル同族体 (セルローストリアセテート, セルローストリブチレート, セルローストリバレレート) が2回らせん構造を有するのに対して, 特異的である。エネルギ一計算および非結合原子間の容認されることのできない接触の有無を調べた結果, 右巻き3_1らせんに比べ, 左巻き3_2らせんの方が低いコンフォーメーションエネルギーを持つ事がわかった。考慮した16のモデルのうち, 最も可能性の高い左巻き3_2らせんのコンフォーメーションにおいては, 側鎖はらせん軸に対しほぼ垂直に伸びた構造を持つ。The conformation of single cellulose tripropionate chain was studied by the virtual bond method considering nonbonded repulsive energy within the residue and between the contiguous residues. From X-ray data, the fiber repeat distance was found to be 1.508nm with systematic absences of threefold screw axis along the molecule. This threefold helical symmetry of cellulose tripropionate is unique among cellulose triester homologues in which the twofold screw axis is predominant. Considering 16 most probable conformations, 8 in right-handed and 8 in left-handed helical conformations, a left-handed 32 helical conformation was most favorable based on conformation analysis and short contact examinations between any pair of nonbonded atoms. The propionyl side chains are considerably extended almost perpendicularly to the helix axis

Norimoto, Misato

Okamura, Keizo

Shutoh, Yuichiro

Tanaka, Fumio

Kyoto University Research Information Repository

Title Conformational Analysis of Cellulose TripropionateAuthor(s)Shutoh, Yuichiro; Okamura, Keizo; Tanaka, Fumio; Norimoto,MisatoCitation京都大学農学部演習林報告 = BULLETIN OF THE KYOTOUNIVERSITY FORESTS (1986), 58: 280-288Issue Date1986-12-20URL http://hdl.handle.net/2433/191842RightType Departmental Bulletin PaperTextversionpublisherKyoto University280 Conformational Analysis of Cellulose Tripropionate Yuichiro SHUTOH， Keizo OKムMURA，Fumio T ANAKA and Misato NORIMOTO セルロースト 1)プロピオネートのコンブォーメーション解析首藤爵一郎・ i荷村虫造・田中文男・則元 京Resume The conformation of sing'le cellulose tripropionate chain was studied by the vil'tual bond method considel'ing nonbonded repulsive e抗告rgywithin th邑 residue and b母tweeJ1 the COJ1-tiguous residues. From X-r乱ydata， the fiber r・epeatdistance was found to be 1. 508nm with systematic absenees of thrcefold s日間waxis along' thc molecule. 'l'his thl'eerold helical symmetry of eellulose tripropionatc is unique among cellulose tr・iestel'homologues in which the twofold screw axis is predominant. Considering 16 most probable conformations， 8 in rigl比例handedand 8 il1 left-handed helical cOl1fol'm乱tions，a left-handed 32 helical cOl1for-mation was most favorable based 0註 conformationanalysis al1d short contaet ex品mil1ationsbetwcen al1y pair of nonbol1ded atoms. The propionyl side chains are considerably extel1ded almost perpendic百larlyto the helix axis. 要旨セルローストワプロピオネート (CTP)の1本の分子鎖について 1残都内および連続する:AA~ま闘の非総合原子関反発エネルギーを考慮したパーチコ.ア Jレボンド j法!こより，コンブォーメーシ罰ン解析を行なった。 X線繊維|請から， CTP の繊維J~ð閣は1.508nm と計算され，消滅則より分子鍛方向に 31商らせんiI1[¥が禄在する。このように分子事¥[¥方向に 3問らせん納岳もつセルローストワプロピオネートの構造は，イ臨のセルローストリエステル同族休(セルローストリアセテート，セルローストワブチレート，セルローストリパレレート)が21TI1らせん1iW;誌を有するのに対して，特典的である。エネルギー計算およびiJI"総合原子問の谷認されることのできない接触の有無を制べた結果，右巻き 31らせんに比べ，1i.器き 32らせんの方が低いコンブォーメーシ g ンエネルギーを持つ事がわかった。考醸した16のモデルのうち誌も可能性の高い11:巻きれらせんのコン281 フォーメーションにおいては，側自由Iまらせんlili.こ対しほほillIf磁tζJIドぴた構造を持つ。1. Introduction The molecular and crystal struetur・Cof cellulose have been extensively studied by Sal'ko et al1吋) in Syracuse and Blackwelp，6) in Cleveland， and the cOl1formatiol1 of cellulose mole-cule and the pacldng oI neighboring chain wel'e well established. Among the aliphatic cellulosc estel' h0l1010gues the confor・l1ationwas detel'l1 ined 011y of cellulose trIacetate by Stipanovic aud Sarko7)， and Roche et al8). The cOl1forl1ational analysis oI high巴1・esterhomologu邑sbecol1es very difficult， because， when one esterifies cellulose with high日raliphatic acid， confol・mationalposition oI side group atoms varies independently !lnd yet enol'l1ously different ways which nωds formidably long eomputer time even with乱 mostadv乱nced巴omputer.1n this study the conformatiol1 of cellulose tripr‘opionate (CTP) 1l101ecule was dctermin・ed based on X-ray data and conformatiol1al allulysis of sil1g1c molecule. 2. Experimental 2.1 Preparation of c'rp CTP wus prepured by思sterifyinga purified rumie fib記rin the mixture of trifluol'・0同ucetic unhydride und propionic ucid. From proton nmr al1alysis， the ramic fiber wus almost fully esterified (degre君。fsubstitution 2，9). A well-oriented CTP film wus obtuil1ed by stretchil1g il1 an oil buth at 1400C to achieve muximal dl'aw 1叫 io(350%). The or・iented film wus Iur・thel'annealed in the oil bath at 1800C to il1pl'ove sharpness oI CTP diffraetion spots. 2.2 X‘ray measul'emel1t The X-ray fib官l'patt日rnwas l'eeorded il1 a flat film cal1era using nickel filtered Cu-Kα r乱diation.3. Resul ts and Discussion 3.1 X-ray structure of CTP '1'he Xω1・ayfibel'・ patternof the oriented CTP fill1 annealed in the oil bath at 1800C is shown in Fig.1. Frol1 the a1 of the layer line diffractions other th札口 equatorial the fibel' l'epeat was foulld to be 1. 508nJn. Since the vil'tual bond length oI g'lucopyranose residue， th在 vectorlinkillg successive glycosidic bridge oxygens， is0.544nm al1d the fiber diag-ral1 s110ws a systematic absence of (001) ald (002) r 告fl色。tions，one c 品1aSSl百1日nethat t抗凶1e引reex-istωs a thr江eωefお!治olds約巴r引九raxisω.tlong' the 11羽は0叫i記∞Cl叫la似l'd心il'問eωtiOlれ.1.']'he systel1utic absenee of (001) and (002) reflectiollS WCl'e fu1'ther confirmed by tilting the ol'iented CTP film by札p-propriate degl'es. Th記 advancepel・l'esiduealong the helix /txis， h value， becomes 0.503ul1 conside1'ing that a threefold screw axis is presen t ulong the molecular axis. This value is cOl1sider吋lyshorter than those oI cellulose (h = 0， 515nll1) as well as ce11ulose triacetate 282 Fig. l X-1'ay l'ibcl' pat丑1'1of celulose t1'Ipl'O備pionat告乱nnealeeI in 乱noil bath乱t180'C. 'rhc Debye-Schcl'l'cl'・ 1・il1gof (lll) plane of CaF2 was used fol' calibl'l¥tiOI1 pUl'pOSC. (h=O. 525 um) indicatil1g CTP has a g臼ntlel' slo]1c. 3.2 詐'loleculal'llodcl of CTP 1"1・omthe X-l'ay clata it was founcl that a thl'efolcl SCl・邑wax is was pl'esen t nlong the fibel' axis， and the crystal-logl'aphic asymmetrie unit was the tripro・pionyl anhydroglucose residue. Onc日thefil'st l'esiclue is tl'ansforl1ecl along the locus of the h邑lix，the contiguous 1'esidu号sa1'ouncl the helix axis al'e easily generated by the helix syl1lmetl'y operation. 3.2. 1 The descriptioll of the residue Th巴 desCl・iptiol1 of the initial tl'ipro-pionyl anhyd1'oglucose resiclue of CTP is shown in Fig. 2， inwhich the virtual bond length between contiguous glycosidic oxygens， V. B.， isrepl'esented by thむ dot-anclべlashedlines. Initi乱1val ues of the bOl1d lengths (1'・1)，the bond angles (01) ald the confol'mational angles (φ1) wel'e obtainecl f1'ol1 thむatomiccoordinates of the l1idcle l'巴sidueof celot1'iose undecaaeetate官'1'hc gl ucosc resid ue of cel ulo日記 1l101ecule is “rigidヘex巴ptfo1' the atol1ie positions of hydl'oxYl1ethyl 0 (6)， ancl the vIl'tual boncl length of al1y of cellu10se clel'ivatives as well as ccllulose hns thc valuc of 0.54111. Fig'ul'e 3 shows the 1'elationships betwe号沿 the vir-tua1 bOlcl length， L， and othcl'・ hむlixpar・ametcrs，in which h，μ， ancl A a1'e th己aclv乱ncepCl' 1'esiclue a10ng thc helix axis， the 810pc of the pitch乱nclthe angle of tU・1pel' r也sidue，respeetively. The va1ues h， 1 Hncl R al'e expressecl in tεrms of L and IJ.'， 乱nc1they are L ・1 .A Sil 1./'， 1'(:08 1-1'，札ncl ・COSf!' • cosec (ー)， l'espectively， and A is 2πtjn， whcl'e t is2 v'"'"" 1"" ...."'..'" ¥ 2 / . ""'1"'""'... V"J 之 CM22 Z y x x Fig. 2 Bond lcngths (1'1)， bOld anglcs (01)， ald confol'mational anglcs (9[，) l'cquil'cd for descriptiol1 of the I・esiduc.Hydrogell atoms !l'e lot ShOWl. numbel' or turns in l'epeat and n is numbel' or r・esiduesper repeat. In c'rp h， t， n and d. values have been determined to be O. 503 nm， 1，3ω3πfrom Xぺaydiagl'am，品川ルsidering the， virtu乱1bond value， L， is always equal to 0.544nm， and oth邑rvalues 1， It and μI b母come0.207nm， O.120nm and 67.60 l'e日制pective1y ror・thebridge oxygens. Among these values h and d. are the same for any or the atoms il1 one r・邑sidue to the corresponding 乱tomor the contiguous residue. Once these parameters are rixed， together with th告 fixedbond lengths， bond angle昌 al1dCOl1rormatiol1al angles，乱l1y atomi巴positiol1Sof one residue can be tl'ansrormed to the con-ti宮uous residues until the hclix comp1etes the turn. Figur邑s4 (a) and (b) show hov干 thecOl1tiguous residues a1・B 宮巴l1erated from the startil1g residue along the right-handed 31， 283 Z Fig. 3 A diagram showing relationship between virtual bond length and helix axis. al1d left-hal1ded 32 helices， l'espectively. The glycosidic bOl1d al1gle， 'r， vari邑sas the al1gle o l'otates， which r日pl'csentsl'otation of the el1tire glycosidic residue around the virtual bond (VB). Thus， by rotating thc 0 angle， one can build Up a1 the possible chail1 conrorma-tions keepil1g threefold helix axis alol1g the chai1110l. x 31 z (α) y x 3， z (b) y Fig. 4 Virtual bond lellgth (VB) of resi品目。 乱泊dhelix parameters (number of residues per turn of helix， n， and advanee of residue along the fiber axis， h) determine positions of atoms il the contiguous residue(ム=2n/ll).Rotational angle of the residue around VB (0) changes glycosidic bond angle， r 284 3.2.2 Conformation of the propiollyl side ehains With respeet to propionyl side chains， cOllformations of 0 (6) propionyl group were varied. Four possible rotatiollal positiollS (g'， g't， tg， and gg + 1800) are shown in Fig. 5. Furthermore in each conformation， cisand trans co註fo1'mations101' CM (6) with respect to C (0) were cOllsidered (Fig.自)， 'Jhis is legitimate since al the atoms in 0 (u)-CA(6)一CM(O)lie il Ole plalle which is the cas♀ in polypeptides. OA (6) gt gg tg gg+180 0 ????????。?????? ???????? ??? ? ?????? ?????。、??????、、?????Fig. 5 Four probablc positions of 0 (0)atoms with rcspect to 0 (5) and C (4) : gt， gg， tgand g富十1800.CM66 C6 CM66 Fig. 6 Two probable conformations of CM (自)with respect to C (6) : (a) trans， and (b) cis. Fillally the glycosidic bOlld allgle r was varied f1'om 1130 to 1230. Withill this allgle rallge the millimum cOllformatiollal ellergy was sought for various conformational posi-tiOlS. 3.3 Calculatiolls of llollbollded l'epulsive energy of isolated CTP chail For the various conformatiolls thus cOllsidered the 1lO1lbollded repulsive ellergy was calculated within Ole residue alld/or between contig'uous r邑sidues.The followillg quadratic llonbonded interatomic potential fUlCtiol (Rpnck) proposed by Williams!1) was used for the calculation12) : n RpnCkロ L;wIJ(do1J-d1u2 (1) wh♀re d01j is llonbonded equilibrium distance between atoms i and j; d1J is actual llonbond母ddistancc between atoms and j: W1J is weighting Iactor for each interaction typej n is nなmbel'of nonbonded contacts. The constants for each pair of乱tomsare given in Table 113). Typical virtual bond angle vs energy plots for the right-handed ald the left-handed CTP oh乱insare given in Figs. 7(a) and 8(a)， l'espectively.、iVithinprobable virtual bond angle range， th色rotationsal'ound C(1ト0(1)， φ，ald 0(1)“C (4/)， 1]1， as well as the glycosidic bOlld al1g1e (τ) wer邑 plottedagainst to the virtual bond angle [Figs. 7(b) and 8(b)]. 1n Fig'. 7， il1which the values were plotted agail1st the virtual bond al1g1e for 乱巴ol1fol'mation of a right.hal1ded CTP [0(6)， gg-ト1800 ; CM(日)， t1'ans J， the ene1'gy minil1ul1 was s邑enat 0 口 300 •The cor1'espol1ding r al1g1e was 123.70 which is too large to accept as the bl'idge al1g1e fol' Ul1y cu1'bohydl'ate compounds Table 1 Weighting faetors for nonbonclecl repulsion term in Eq.(l) (for clj > clOlj， wロ0). Interaction type clolj， A w 一一一一一一一一一C ・・・C_ 3.70 3.00 C...O 3.60 3.00 C......H 3.30 1.35 0...0 3.60 3.00 0・・・H 3，25 1.40 H......H 3.20 0，50 285 whieh ral1ges between 1130 al1d 118014)， Besides， an unacceptable short COl1tuct was noticed betweel1 0(3) und 1沢1)utOl1S， which l'uised Rpack value， and this confo1'l1ation wus discal'ded. On the other hand， inFig. 8， inwhich the valu邑swe1'e plotted agail1st the virtuul bond ungle fol' u confol'l1ation of 乱 left偽handed CTP [0 (6)， gt; CM (6)， trans]， thc enC1'gy minim Ul1 was secn at 0口 2250，乱ndthe C01'1'母spondingr angle wus 117.70 which is in the l'ange of the b1‘idge angle for む乱rbohyd1'atecompounds. Further・mo1'e，ねosho1'・tcontuct was noticec1 between uny pail' of atoms. 1部 f (α) @ ( @ 〉、 i'Eコ:!l @ @ @ c J= • • はJ;ぉ@ } 《L. 50冒• • • • • o • • • 124 • (b) 40 τ ‘' ‘つ. 20 @ " " 120 o 且干 o @ " -畠 A， O A d. a 0 0。φ d. m ~ 18 @ -20 ~ 告。、 16 Or • @ -40 ミテ@ ・ d. ‘' -・60 E O 1-' 14 中d.A 告 。o0。" d."'p 。。12 d. " 。。 サ0-&30 50 70 140 160 180 θ(deg) ー…+Fig. 7 Relationships between virtual boncl rotation ancl conformational enel'gy (a)， ancl resulting r， <t ancl <t angles (b) for a l'ight-hanclecl CTP， where 0 (6)is gg十 1800，ancl CM (6) is trans positions. 286 • • • • • • ZE拍. @ • @ 30 ム剛g _ (b) @ 122 80 eo w o φ 。。。。60 • 。「惨 • 01: 。 g A “ A 18 ←3・ 。 ゐ事 40 ( 6 匂0ω 3 .官U 116 • A Il 0 • d包 • o 0 0 0 20 E • そヨド1-' 114 A ゐ ijf • O "0 c 12 A A -20 0 A @ 200 220 240 260 280 300 320 e (deg.) 冊目司『目司~Fig.8 H冷lationshipsbetween virtual bond rotation and ωnform乱tionalenergy (a)， 乱ndthe resulti担g7:，ゆ ando angles (b) for・aleft・handedCTP， where 0 (6) is gt， and CM 削除 transpositions. Table 2 Dependence of total repulsive ener・gy，Hpncl<， for different models. Models of CTP Hpack 7: (0) (/) (0) !lf (0) helix 06 CM6 宮宮 C1S 42.543 121.9 -3.4 国75.6trans 41. 449 121. 9 同3.4 -75‘6 31 gt 巴IS 41.911 123.7 自0.3 7ー8.3trans 39.130 123.7 叩0.3 時78.3l'ight t宮 CIS 42.705 123.7 制0.3 -78.3 handed tl'a自S 40.738 123.7 -0.3 -78.3 gg+180。 CIS 40.210 123.7 -0.8 -78.8 trans 38.501 123.7 一0.3 -78.3 gg ClS 39.396 114.9 59.6 5.4 trans 38.458 114.9 59.6 5.4 32 gt C1S 39.295 117.7 70.3 時7.9trans 36.279 117.7 70.3 時7.9left tg 也IS 41. 979 121.1 78.1 “18.1 handed tl'ans 44.130 122.5 80.8 同 21.5gg+180。 C1S 38.728 117.7 70.3 四7.9tl'ans 37.048 117.7 70.8 目7.9The minimum 1もpackvalues for sixteen conformation models of CTP are listed in Table 2， eight for right-handed and eight for left-handed helices together with the resulting， o， 1ft and r乱ngles.For・eachhelix foul' 0 (6) position器， and for each 0 (6)， trans and cis CM (6) positions were considel'ed. The Rpack values in the left-handed helix were lowel' except fol' the model of 0(6) tg and CM (6) tl'ans. The lowest confol'mational en記l'gyam-ong sixteen possible models was the 1eft-handed 32 helix with 0(6) gt and CM (6) tl'ans， and Rpack va1ue was 36. 279. No shol't contact was noticed in this mode1， and we decided that this was the most pl'obable chain confol'matiol1 or CTP. Thc pl'ojections or al1 the atomic cool'dinates within one comp1ete helix， one pel'p号ndicu1al' and the othel' paral1e1 to the helix， al'e shown in Fig. 9. Acknowledgement The authol's express theil' sincel'e ap-pl'eciation to Pl'of. Anato1e Sal'ko， Depal't-ment of Chemistl'Y， State Unive1'sity of New YOl'k， College of Environmental Science and FOl'estl'y ro1' his illvaluable discussion and commen t， alld fol' the use 287 Fig. 9 Pl'ojetions of the eomplet母threcr♀sidues of thc left-handed 32 helix model 01 CTP， (a) x・yprojeetion， and (b) y-z projection. of PS79 computel' pl'ogl'am. This wOl'k isSuppol'ted by Scielltific Reseal'ch Gl'alt No.60560176 (1985) or Ministry of Edu巴atiol，Sciellce and Cultu1'e， which is g1'eatly ackllowledged. 4. References 1) SARKO， A.and MUGGLI， R.: Paeking analysis of carbohydrates and polys乱ccharides.m. Valonia aelulose and elulose I. Maeromolecules. 7. 486-494， 1974 2) WOODCOCK， C.and SARI<O， A.: Packing analysis of carbohydrates and polysωcharides. 1. Mole-ωla1' and erystal struct羽1'eof native ramie celulose. Macromolee祖108.13. 1183-1187， 1980 3) SARKO， A.， SOUTHWICI<， J. and HAYASHI， J.: Paeking analysis of cal'、bohydratesa品dpolysac-charides. 7. Crystal structure of cel1ulose廊1and its rclationship to othe1' cel1ulose polymorphs. Macromoleeules. 9. 857-863， 1976 288 4) STIPANOVIC， A. J. and SARKO， A.: Paeki丑ganalysis 01' carbohydrates alld polysacchal'idcs. 6. Moleculal' and crystal structu1'・e01' regenerated cellulose立.Macromolecules. 9. 851-857， 1976 5) GARDNER， K. H. and BLACKWELL， J.: Thc structure 01' n乱tivecellulose. Biopolymers. 13. 1975-2001， 1974 6) KOLPAK， F.J. and BLACKWELL， J.:Detぽ mination01' thc stl'uctul'e 01' cellulose江.Mael'omole-cules. 9. 273-278， 1979 7) 含rIPANOVIC，A. J. and SARKO， A.: Molecular and crystal strucもul'e01' cellulose triacetate I， a parallel chain structul'e. Polymel'. 19. 3叩8，1978 8) ROCI-E， E.， CHANZY， H.， BOUDEULLE， M.， MARCHESSAULT， R. H. and SUNDARARAJAN， P. R.: Three-dimensional crystalline str・ucture01' cellulose triacetate I. Macromolecules. 1. 86-94， 1978 9) PEREZ， S.and BRISSE， F.: The crystal a担dmolecula1' st1'uctu1'e 01'乱 trisaccharide，s -cellotriose undecaacetat告 1，2，3，6・tet1'a鴨0・acetyl-4・O-C2，3，6-tri-O同乱ωtyl-4-0-(2，3， 4， 6ωtetra-O-acetyl-s-D-glucopyranosyl) -s-D-gl日copYl'anosyl)-s四P四glucopyl'乱nose.Act乱 Cryst.B33. 2578-2584， 1977 10) SUNDARARAJAN， P. R. and MARCHESSAULT， R. H.: Virtual bond methods in conformational analysis 01' polym官1's.Can. J. Chem.， 53. 3563-3566， 1975 11) WILLIAMS， D.E.: A method 01' calcul乱tingmoleculal' and 01'・ystalstl'uctures. Acta Cryst. A25. 464“470， 1969 12) ZUGENMAIER， P. and SARKO， A.: Packing 乱llalysis01' ca1'bohydrates alld polysacch乱rides.1. MOllosa古charides.Acta Cl'yst. B28. 3158-3166， 1972 13) ZUGENMAIER， P.alld SARKO， A.: In “Fibel' Difl'uction M母thods"(FRENCH， A. D.乱担dGARDNER， K. C. H.， ed). ACS Symposium Sel'ies No.141， Americall Chemical Society， Washillgtoll D. C. 225pp， 1980 14) SUNDARALINGAM， M.: Some aspects 01' stereochemistry and hydrogell bOllding 01' carbohydrates l'ela ted to polys品ccharidecOllform乱tio担s.Biopolymers. 6. 189-213， 1968 

セルローストリプロピオネートのコンフォーメーション解析

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セルローストリプロピオネートのコンフォーメーション解析

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