Conformation of acetylcholine at muscarinic nerve receptors: Crystal and molecular structure of 2-trimethylammoniummethyl-5-methyl furan iodide (5-methylfurmethide iodide)

2-Trimethylammoniummethyl-5-methyl furan (5-methylfurmethide) is a potent cholinergic agonist at muscarinic nerve receptors. The conformation of the molecule, as shown by crystal structure analysis, is restricted by steric hindrance. The only similar conformation of acetylcholine has τ(N⁺CCO) synclinal and τ(CCOC) antiplanar. This is the conformation found in solution and in crystals of the chloride, and it is believed to be the one relevant to interaction with muscarinic nerve receptors.     

Conformation of 2,3-diformylglycerol, a model compound of membrane phospholipids

The conformations of 2,3-diformylglycerol, a model compound of the diacylglycerol portion of phospholipids, were analyzed both by the classical potential function method and by the INDO molecular orbital method. The results suggest that in membranes, the conformation of the diacylglycerol portion of phospholipids is such that the two ester planes of the β- and γ-hydrocarbon chains stack in an antiparallel way with the dihedral angles β′{C(3)C(2)O(21)C(21)} ? 270° and γ₁{C(2)C(3)O(31)C(31)} ? 270°.     

Refinement of human lysozyme at 1.5 Å resolution analysis of non-bonded and hydrogen-bond interactions

The structure of human lysozyme has been crystallographically refined at 1.5 Å resolution by difference map and restrained least-squares procedures to an R factor of 0.187. A comprehensive analysis of the non-bonded and hydrogen-bonded contacts in the lysozyme molecule, which were not restrained, revealed by the refinement has been carried out. The non-bonded CC contacts begin at ~3.45 Å, and the shorter contacts are dominated, as expected, by interactions between trigonal and tetrahedral carbon atoms. The CO contact distances have a “foot” at 3.05 Å. The CN distance plot shows a significant peak at 3.25 Å, which results from close contact between peptide NHs and carbonyl carbons involved in N_iC′_{i ? 2} interactions in α-helices and reverse turns. The distances involving sulphur atoms discriminate SC trigonal interactions at 3.4 to 3.6 Å from SC tetrahedral interactions at 3.7 Å. All these types of non-bonded interactions show minimum distances close to standard van der Waals' separations.Analysis of hydrogen-bond distances has been carried out by using standard geometry to place hydrogen atoms and measuring the XHO distances. On this basis, there are 130 intramolecular hydrogens: 111 NHO bonds, of which 69 are between main-chain atoms, 13 between side-chain atoms and 29 between mainchain and side-chain atoms. If a cluster of four well-defined internal water molecules is included in the protein structure, there is a total of 19 OHO hydrogen bonds. The mean NO, NHO distances and HN?O angles are 2.96 ± 0.17 Å, 2.05 ± 0.18 Å and 18.5 ± 9.6 °, and the mean OO, OHO distances and HÔO angles are 2.83 ± 0.19 Å, 1.98 ± 0.26 Å and 23.8 ± 13.4 °. The distances agree well with standard values, although the hydrogen bonds are consistently more non-linear than in equivalent small molecules. An analysis of the hydrogen-bond angles at the receptor atom indicates that the α-helix, β-sheet and reverse turn have characteristic angular values. A detailed analysis of the regularity of the α-helices and reverse turns shows small but consistent differences between the α-helices in lysozyme and the current standard model, which may now need revision. Of the 21 reverse turns that include a hydrogen bond, the conformations of 19 agree very closely with four of the five standard types. We conclude that the restrained least-squares method of refinement has been validated by these analyses.     

Localization of repetitive and unique DNA sequences neighbouring the rabbit beta-globin gene

The structure of oxymyoglobin has been refined at 1·6 Å resolution, using diffractometer data collected at ?12 °C. The crystallographic R factor is 0·159, and the atomic positions are known to 0·1 Å accuracy in internal segments of the molecule.The iron atom lies 0·22(3) Å from the plane of the porphyrin, 0·25 Å closer than in deoxymyoglobin, and the F helix has moved by a similar amount. Oxygen binds to the iron in a bent, end-on arrangement, with FeOO = 115(5) ° and FeO = 1·83(6) Å. The mean FeN(porphyrin) bond length is 1·95(6) Å, 0·08 Å shorter than in deoxymyoglobin, but the difference is not significant compared to the experimental error. FeN_ε(His8F) is 2·07(6) Å, the same as in model compounds. Movements of the haem, iron, F helix and FG corner on oxygenation are similar to those found in the T-R state transition in haemoglobin, but are smaller in magnitude.     

An infrared study of various nitrated polysaccharides and their structural characterisation

Infrared absorption spectra for a number of polysaccharides and their nitrated derivatives have been obtained. The frequency range 730–960 cm^?1 is useful for identification of the polysaccharides, and the region 900–1350 cm^?1 is more suitable for distinguishing the nitrated materials. The strong intensity of the nitrate bands limits the interpretation of spectra below 960 cm^?1, but above this frequency the absorption bands of nitrated polysaccharides are generally sharper and more clearly defined than the corresponding bands of the parent polysaccharides. Data on the COC bridge, CC ring, CO, and COH frequencies and on the CH deformation and stretching frequencies have been obtained. The use of i.r. spectroscopy for the quantitative determination of nitrate groups in nitrated polysaccharides is discussed.     

The crystal structure of 2-deoxy-β-d-arabino-hexopyranose at −150°

2-Deoxy-β-d-arabino-hexopyranose, C₆H₁₂O₅, is orthorhombic, P2₁2₁2₁, with cell dimensions at ?150° [20°], a = 6.484(2) [6.510(3)], b = 10.364(2) [10.427(4)], c = 11.134(3) [11.153(5)] Å, V = 748.2 [757.1] ų, Z = 4, D_x = 1.457 [1.440], and D_m = [1.455] g.cm^?3. The intensities of 1269 reflections were measured by using MoKα radiation. The structure was solved by direct methods, and refined by full-matrix least-squares, with anisotropic, thermal parameters for the carbon and oxygen atoms, and isotropic parameters for the hydrogen atoms. The pyranose has the ⁴C₁(d) conformation, with puckering parameters Q = 0.563 Å, θ = 3.9°, and ? = 350.3°. The departure from ideality is very small, and less than that in β-d-glucopyranose, Q = 0.584 Å and θ = 6.9°. The β-glycosidic, CO bond is short, 1.383(4) Å, and the OCOH torsion angle is ?87°, consistent with the anomeric effect. The hydrogen-bonding scheme consists of infinite chains, with side chains terminating at a ring-oxygen atom.     

31P n.m.r. studies of complexes of NADPH and NADP+ with Escherichia coli dihydrofolate reductase

We have measured the ³¹P n.m.r. spectra of NADP⁺ and NADPH in their binary complexes with Escherichia coli dihydrofolate reductase and in ternary complexes with the enzyme and folate or methotrexate. The ³¹P chemical shift of the 2′ phosphate group is the same in all complexes; its value indicates that it is binding in the dianionic state and its pH independence suggests that it is interacting strongly with cationic residue(s) on the enzyme. Similar behaviour has been noted previously for the complexes with the Lactobacillus casei enzyme although the ³¹P shift is somewhat different in this complex, possibly due to an interaction between the 2′ phosphate group and His 64 which is not conserved in the E. coli enzyme. For the coenzyme complexes with both enzymes ³¹POC₂¹H_2′ spin-spin interactions were detected (7.5–7.8 Hz) on the 2′ phosphate resonances, indicating a POC₂H_2′ dihedral angle of 30 or 330 : this is in good agreement with the value of 330° measured in crystallographic studies¹ (Matthews et al., 1978) on the L. casei enzyme. NADPH-MTX complex. The pyrophosphate resonances are shifted to different extents in the various complexes and there is evidence that there is more OPO bond angle distortion in the E. coli enzyme complexes than in those with the L. casei enzyme. The effects of ³¹POC₅¹H_5′ spin coupling were detected on one pyrophosphate resonance and indicate that the POC₅H_5′ torsion angle has changed by at least ～30° on binding to the E. coli enzyme: this is considerably less than the distortion (～50°) observed previously in the L. casei enzyme complex.     

Raman spectroscopic analysis of the sodium salt of kappa-carrageenan and related compounds in solution

Laser-Raman spectra of Na⁺ kappa-carrageenan, Na⁺ neocarrabiose 4-sulphate, and neocarrabiose in the region 700–1500 cm⁻¹ are reported for solutions in H₂O and D₂O. The C-1-H-1α vibration, coupled with COH related modes, is assigned to a band at 840 cm⁻¹, close to the maximum of the symmetrical COS stretching (∼850 cm⁻¹). The symmetrical SO stretch is proposed to occur near 1040 cm⁻¹ and is probably coupled with COH vibrations which give rise to strong bands in the region 1000–1100 cm⁻¹. The intense band in the region 730–740 cm⁻¹ is ascribed to a complex ring vibration.     

6-Azauridine, a nucleoside with unusual ribose conformation. The molecular and crystal structure

The cytostatic analogue ribo-6-azauridine crystallizes in the orthorhombic space group P2₁2₁2₁ with eight molecules per unit cell of dimensions $\text{a = 20.230, b = 7.709, c = 12.863}\text{A}\text{?}$. A trial structure was obtained by direct methods. Least-squares refinement of co-ordinates and anisotropic thermal parameters based on 1998 reflections measured on a four-circle diffractometer led to a discrepancy index R = 4.0%. Like uridine, 6-azauridine has the anti conformation about the glycosidic bond and a C(3′)-endo sugar pucker. Unlike uridine, it exhibits a close approach of N(6) to C(2′) at only 2.814 and 2.844 Å in the two independent molecules, and a C(5′)(5′) bond that is gauche to C(4′)O(1′) but trans to C(4′)C(3′); this conformation about a C(4′)C(5′) bond has never been observed before for C(3′)-endo puckered riboses in the crystalline state. The crystal structure displays a pseudo-A face centering and very similar conformational parameters for the two independent molecules. Every OH and NH group in the structure serves as a proton donor in a hydrogen bond, including an unusual N(3)—H(3) … O(1′) link. Molecular orbital calculations by the extended Hückel method indicate that from uridine to 6-azauridine the net charge changes sign at ring positions 5 and 6 and disappears at 1.     

Synthesis and crystal structure of (pipzH2)2Mo2Cl8·4H2O (pipz = piperazine)

The title compound (pipzH₂)₂Mo₂Cl₈·4H₂O (pipz = piperazine),was isolated from the solution of (morphH)₂Mo₂Cl₆(H₂O)₂ in HCl 1:1 by addition of (pipzH₂)Cl₂. This reaction indicates the reversibility of the substitution of chloride ions in Mo₂Cl₈^4? by water molecules. (pipzH₂)₂Mo₂Cl₈·4H₂O crystallizes in the Pbca space group, with a = 15.154(2), b = 13.170(2), c = 12.208(2) Å and Z = 4. The structure was solved by the Patterson method and refined to the unweighted and weighted residuals of 0.050 and 0.048. The crystal structure is built form Mo₂Cl₈^4?, (pipzH₂)²⁺ and H₂O. The MoMo distance of 2.129(3) Å is the shortest one found in all structurally-characterised Mo₂X₈^4? (X = Cl, Br) anions. Four independent MoCl distances are 2.456(3), 2.445(3), 2.463(4) and 2.455(4) Å. The (pipzH₂²⁺ exists in a usual chair conformation. There is a network of hydrogen bonds of the type NH?Cl, NH?O, OH?Cl and OH?O between the ions and water molecules.     

Transition-metal(II) thiocyanate coordination compounds containing 4-allyl-1,2,4-triazole. Structure and magnetic properties.

The synthesis and characterisation of a series of dinuclear and polynuclear coordination compounds with 4-allyl-1,2,4-triazole are described. Dinuclear compounds were obtained for Mn(II) and Fe(II) with composition [M₂(Altrz)₅(NCS)₄], and for Co(II) and Ni(II) with composition [M₂(Altrz)₄(H₂O)(NCS)₄](H₂O)₂. The crystal structure of [Co₂(Altrz)₄(H₂O)(NCS)₄](H₂O)₂ was solved at room temperature. It crystallizes in the monoclinic space group P2₁/n. The lattice constants are a = 18.033(3) Å, b = 13.611(2) Å, c = 15.619(3) Å, β = 92.04(2)° Z = 4. One cobalt ion has an octahedrally arranged donor set of ligands consisting of three vicinal nitrogens of 1,2-bridging triazoles (CoN = 2.14–2.15 Å), one terminal triazole nitrogen (CoN = 2.12 Å) and two N-bonded NCS anions (CON = 2.08 Å). The other Co(II) ion has the same geometry, but the terminal triazole ligand is replaced by H₂O (CoO = 2.15 Å). The crystal structure is stabilised by hydrogen bonding through H₂O molecules, S-atoms of the NCS anions and the lone-pair electron of the monodentate triazole. The magnetic exchange in the Mn, Co and Ni compounds is antiferromagnetic with J-values of ?0.4 cm^?1, ?10.9 cm^?1 and ?8.7 cm^?1 respectively. The Co compound was interpreted in terms of an Ising model. For [Zn₂(Altrz)₅(NCS)₂]∞[Zn(NCS)₄], [Cu₂(Altrz)₃(NCS)₄]∞ and [Cd₂(Altrz)₃(NCS)₄]∞ chain structures are proposed. In the Cu compound thiocyanates appear to be present, bridging via the nitrogen atom, as deduced from the IR spectrum.     

Synthesis and crystal and molecular structure of a methyl N,N-diethylcarbamylmethylenephosphonato dysprosium thiocyanate complex

Bis-Methyl N,N-diethylcarbamylmethylenephosphonato dysprosium thiocyanate, Dy[O₂P(OCH₃)CH₂C(O)N(C₂H₅)₂]₂(NCS) was prepared from the combination of ethanolic solutions of Dy(NCS)₃·xH₂O and (CH₃O)₂P(O)CH₂C(O)N(C₂H₅)₂. The complex was characterized by infrared and NMR spectroscopy, and single crystal X-ray diffraction methods. The crystal structure was determined at 25 °C from 3727 independent reflections by using a standard automated diffractometer. The complex was found to crystallize in the monoclinic space group P2₁/c with a = 13.282(4) Å, b = 19.168(5) Å, c = 9.648(2) Å, β = 90.09(2)°, Z = 4, V = 2456.4 ų and ?_cald = 1.72 g cm^?3. The structure was solved by standard heavy atom techniques, and blocked least-squares refinement converged with R_f = 4.7% and R_wF = 4.9%. The Dy atom is seven coordinate and bonded in a bidentate fashion to two anionic phosphonate ligands [O₂P(OCH₃)CH₂C(O)N(C₂H₅)₂^?] through the carbonyl oxygen atoms and one of two phosphonate oxygen atoms. In addition, each Dy atom is coordinated to two phosphonate oxygen atoms from two neighboring complexes and to the nitrogen atom of a thiocyanate ion. This coordination scheme gives rise to a two-dimensional polymeric structure. Some important bond distances include DyNCS 2.433(8) Å, DyO(carbonyl)_avg 2.39(2) Å, DyO(equat. phosphoryl)_avg 2.303(8) Å, DyO(axial phosphoryl)_avg 2.25(2), PO(phosphoryl)_avg 1.493(3) Å and CO(carbonyl)_avg 1.25(1) Å.     

Conformational dependence of CH(CD)-strechings in D-glucose and some deuterated derivatives as revealed by infrared and raman spectroscopy

The Raman and i.r. spectra in the CH- and CD-stretching region of D-glucose and five selectively deuterated derivatives in the solid state have been recorded. The CH (CD) bonds have different force constants depending on their position and conformation in the pyranose ring and on the dihedral angle HCOH (DCOH). Calculations of the intensities of the i.r. bands confirm these conclusions. Modifications of the force field are proposed that account for the changes in the spectra for solutions in D₂O, which are useful for the interpretation of vibrational c.d. spectra.     

NH2-terminal sequences of DNA-, heparin-, and gelatin-binding tryptic fragments from human plasma fibronectin

NH₂-terminal sequence analysis was performed on subregions of human plasma fibronectin including 24,000-dalton (24K) DNA-binding, 29,000-dalton (29K) gelatin-binding, and 18,000-dalton (18K) heparin-binding tryptic fragments. These fragments were obtained from fibronectin after extensive trypsin digestion followed by sequential affinity purification on gelatin-Sepharose, heparin-agarose, and DNA-cellulose columns. The gelatin-binding fragment was further purified by gel filtration on Sephadex G-100, and the DNA-binding and heparin-binding fragments were further purified by high-performance liquid chromatography. The 29K fragment had the following NH₂-terminal sequence: AlaAlaValTyrGlnProGlnProHisProGlnProPro (Pro)TyrGlyHis HisValThrAsp(His)(Thr)ValValTyrGly(Ser) ?(Ser)?-Lys. The NH₂-terminal sequence of a 50K, gelatin-binding, subtilisin fragment by L. I. Gold, A. Garcia-Pardo, B. Prangione, E. C. Franklin, and E. Pearlstein (1979, Proc. Nat. Acad. Sci. USA76, 4803–4807) is identical to positions 3–19 (with the exception of some ambiguity at position 14) of the 29K fragment. These data strongly suggest that the 29K tryptic fragment is included in the 50K subtilisin fragment, and that subtilisin cleaves fibronectin between the Ala²Val³ residues of the 29K tryptic fragment. The 18K heparin-binding fragment had the following NH₂-terminal sequence: (Glu)AlaProGlnProHisCysIleSerLysTyrIle LeuTyrTrpAspProLysAsnSerValGly?(Pro) LysGluAla?(Val)(Pro). The 29K gelatin-binding and 18K heparin-binding fragments have proline-rich NH₂-terminal sequences suggesting that they may have arisen from protease-sensitive, random coil regions of fibronectin corresponding to interdomain regions preceding macromolecular-binding domains. Both of these fragments contain the identical sequence ProGlnProHis, a sequence which may be repeated in other interdomain regions of fibronectin. The 24K DNA-binding fragment has the following NH₂-terminal sequence: SerAspThrValProSerProCysAspLeuGlnPhe ValGluValThrAspVal LysValThrIleMetTrpThrProProGluSerAla ValThrGlyTyrArgVal AspValCysProValAsnLeuProGlyGluHisGly Gln(Cys)LeuProIleSer. The sequence of positions 9–22 are homologous to positions 15–28 of the α chain of DNA-dependent RNA polymerase from Escherichia coli. The homology observed suggests that this stretch of amino acids may be a DNA-binding site.     

Coordination modes of polydentate ligands. 4. The crystal and molecular structure of an oxo-bridged iron(III) complex containing a pentadentate imino-alkoxy ligand

In the presence of Fe³⁺, template condensation of the fluorinated keto-alcohol CH₃C(O)CH₂C- (CF₃)₂OH with the triamine CH₃C(CH₂NH₂)₃ leads to two products: a fully condensed, imino-alkoxy, iron(III) complex, Fe{CH₃C[CH₂NC(CH₃)CH₂C(CF₃)₂O]₃}, and a partially condensed iron(III) complex, O{FeCH₃C[CH₂NC(CH₃)CH₂C(CF₃)₂O]₂(CH₂NH₂)}₂, in which two six-coordinate iron(III) centers are linked by an oxide ion. A complete crystal and molecular structure determination of the latter has been made.Crystals are monoclinic, space group C2/c, a= 13.886(4); b=23.206(5); c=15.241(4) Å; β= 106.55(2)°; V=4708 ų; Z=4. Least-squares refinement on F of 322 variables using 2627 observations converged at a conventional agreement factor of 3.8%. The Fe to bridging oxide distance is 1.811(1) Å, the FeFe distance 3.468 Å, and the FeOFe angle 146.6(2)°. A comparison is made between this structure and those of natural hemerythrin systems.     

Purification and characterization of a glycolic acid (GA) oxidase active toward diglycolic acid (DGA) produced by DGA-utilizing Rhodococcus sp. No. 432

Diglycolic acid (DGA) oxidizing activity was found in crude extracts of Rhodococcus sp. no. 432 grown in DGA. Glycolic acid (GA) oxidase was purified approximately 80 times by treatment with streptomycin sulfate, precipitation with (NH₄)₂SO₄, chromatographies with DEAE-cellulose, DEAE-Toyopearl and Butyl-Toyopearl, and gel filtration on Toyopearl HW-55. The purified GA oxidase was almost homogeneous on sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis. The purity was calculated to be more than 95%. The molecular weight of the enzyme, which appeared to consist of three identical units, was 158,000. Each subunit of GA oxidase included one molecule of FAD as a cofactor. The isoelectric point of the enzyme was around 5.3. GA oxidase was stable below 30°C and at the pH range of 6.0–8.5. The optimum pH and temperature were around 7.5 and 40°C, respectively. Oxygen, cytochrome c, ferricyanide and 2,6-dichlorophenol indophenol (DCIP) acted as an electron acceptor. The activity of GA oxidase was strongly inhibited by potassium cyanide, quinine, quinacrine, monoiodoacetate, 1,4-benzoquinone and some heavy metal ions. GA oxidase also had activity in DGA, GA, glyoxylic acid (GOA), methoxy acetate, ethoxy acetate and l-malate. Alcohols and other organic acids were not oxidized by the enzyme. The apparent K_m values for DGA, GA and GOA were about 26.7, 0.5 and 4.4 mM, respectively. The reaction products from DGA were supposed to be GOA and GA by the enzymatic assays. The reaction mechanism of GA oxidase in oxidation of DGA was supposed to be as follows: HOOCH₂COCH₂COOH+H₂O+acceptor→HOOCCHO+HOOCCH₂OH+ reduced acceptor.     

Synthesis and spectroscopic properties of CpRuCl(R-DAB(4e)) and CpRuCo(CO)3(R-DAB(6e)). Part XVII. X-ray structure determination of CpRuCo(CO)3(t-Bu-DAB(6e))

CpRuCl(PPh₃)₂ reacted with excess R-DAB in refluxing toluene to give CpRuCl(R-DAB(4e)) (1a: R = i-Pr; 1b: R = t-Bu; 1c: R = neo-Pent; 1d: R =p-Tol). ¹H NMR and ¹³C NMR spectroscopic data indicated that in these complexes the R-DAB ligand is bonded in a chelating 4e coordination mode.Reaction of 1a and 1b with one equivalent of [Co(CO)₄]⁻ afforded CpRuCo(CO)₃(R-DAB(6e)) (2a: R = i-Pr; 2b: R = t-Bu). The structure of 2b was determined by a single crystal X-ray structure determination. Crystals of 2b are monoclinic, space group P2₁/n, with four molecules in a unit cell of dimensions: a = 16.812(4), b = 12.233(3), c = 9.938(3) Å and β = 105.47(3)°. The structure was solved via the heavy atom method and refined to R = 0.060 and R_w = 0.065 for the 3706 observed reflections. The molecule contains a RuCo bond of 2.660(3) Å and a cyclopentadienyl group that is η⁵-coordinated to ruthenium [RuC(cyclopentadienyl) = 2.208(3) Å (mean)]. Two carbonyls are terminally coordinated to cobalt (CoC(1) = 1.746(7) and CoC(2) = 1.715(6) Å) while the third is slightly asymmetrically bridging the RuCo bond (RuC(3) = 2.025(6) and CoC(3) = 1.912(6) Å). The RuC(3)O(3) and CoC(3)O(3) angles are 138.4(5)° and 136.5(5)°, respectively. The t-Bu-DAB ligand is in the bridging 6e coordination mode: σ-N coordinated to Ru (RuN(2) = 2.125(4) Å), μ₂-N′ bridging the RuCo bond and η²-CN coordinated to Co (RuN(1) = 2.113(5), CoN(1) = 1.941(4) and CoC(4) = 2.084(5) Å). The η²-CN′ bonded imine group has a bond length of 1.394(7) Å indicating substantial π-backbonding from Co into the anti-bonding orbital of this CN bond.¹H NMR spectroscopy indicated that 2a and 2b are fluxional on the NMR time scale. The fluxionality of 6e bonded R-DAB ligands is rarely observed and may be explained by the reversible interchange of the σ-N and η²-CN′ coordinated imine parts of the R-DAB ligand.     

Developmental process of sun and shade leaves in Chenopodium album L.

The authors’ previous study of Chenopodium album L. revealed that the light signal for anatomical differentiation of sun and shade leaves is sensed by mature leaves, not by developing leaves. They suggested that the two‐cell‐layered palisade tissue of the sun leaves would be formed without a change in the total palisade tissue cell number. To verify that suggestion, a detailed study was made of the developmental processes of the sun and shade leaves of C. album with respect to the division of palisade tissue cells (PCs) and the data was expressed against developmental time (leaf plastochron index, LPI). The total number of PCs per leaf did not differ between the sun and shade leaves throughout leaf development (from LPI ?1 to 10). In both sun and shade leaves, anticlinal cell division of PCs occurred most frequently from LPI ?1 to 2. In sun leaves, periclinal division of PCs occurred synchronously with anticlinal division. The constancy of the total number of PCs indicates that periclinal divisions occur at the expense of anticlinal divisions. These results support the above suggestion that two‐cell‐layered palisade tissue is formed by a change of cell division direction without a change in the total number of PCs. PCs would be able to recognize the polarity or axis that is perpendicular to the leaf plane and thereby change the direction of their cell divisions in response to the light signal from mature leaves.     

Crystal structure of methyl 2,6-dichloro-2,6-dideoxy-3,4-O-isopropylidene-α-D-altropyranoside. A pyranoside system close to a skew-boat conformation

The crystal structure of methyl 2,6-dichloro-2,6-dideoxy-3,4-O-isopropylidene-α-D-altropyranoside (1) has been determined by X-ray diffraction. The compound crystallizes in the orthorhombic system, space group P2₁2₁2₁, with unit-cell dimensions a  7.932, b  8.133, and c  20.447 Å. The structure was solved by the heavy-atom method and refined by the least-squares technique to an R value of 0.047 by using 736 intensities measured on a diffractometer. The pyranoside ring is close to a skew-boat conformation, with C-2 and C-5 being maximally displaced from the least-squares plane through the remaining four atoms. The H-1H-2 dihedral angle of  158° is in agreement with the J_1,2 value of 4.5 Hz. Thus the solid-state conformation appears to correspond with the conformation in solution. The dioxolane ring is in a twist form, with O-4 and, C-8 puckered on opposite sides of the plane of the other ring atoms. The pyranose-ring substituents are in equatorial and pseudoequatorial orientations. The hydrogen atoms at C-3 and C-4 are in a cis arrangement. The orientations of both the methoxyl group and the chloromethyl group with respect to the ring are gauche—trans. The exocyclic anomeric C-1O-1 bond-distance (1.39 Å) is the shortest CO bond in the structure. The intracyclic CO bonds are significantly different, C-1O-5 being less than C-5O-5.     

Isolation of bacteriophage MX4, a generalized transducing phage for Myxococcus xanthus.

The structure of α-chitin has been determined by X-ray diffraction, based on the intensity data from deproteinized lobster tendon. Least-squares refinement shows that adjacent chains have alternating sense (i.e. are antiparallel). In addition, there is a statistical distribution of side-chain orientations, such that all the hydroxyl groups form hydrogen bonds. The unit cell is orthorhombic with dimensions a = 0.474 ± 0.001 nm, b = 1.886 ± 0.002 nm and c = 1.032 ± 0.002 nm (fiber axis); the space group is P2₁2₁2₁ and the cell contains disaccharide sections of the two chains passing through the center and corner of the ab projection. The chains form hydrogen-bonded sheets linked by CO…HN bonds approximately parallel to the a axis, and each chain has an O-3′H…O.5 intramolecular hydrogen bond, similar to that in cellulose. Adjacent chains along the ab diagonal have different conformations for the CH₂OH groups: on one chain these groups form O.6H…O.6′ intermolecular hydrogen bonds to the CH₂OH group on the adjacent chain along the ab diagonal. The latter group is oriented to form an intramolecular O.6′H…O.7 bond to the carboxyl oxygen on the next residue. The results indicate that a statistical mixture of CH₂OH orientations is present, equivalent to half oxygens on each residue, each forming inter- and intramolecular hydrogen bonds. As a result the structure contains two types of amide groups, which differ in their hydrogen bonding, and account for the splitting of the amide I band in the infrared spectrum. The Inability of this chitin polymorph to swell on soaking in water is explained by the extensive intermolecular hydrogen bonding.