Synthesis and characterization of homochiral polymeric S-malato molybdate(VI): toward the potentially stereospecific formation and absolute configuration of iron-molybdenum cofactor in nitrogenase

Reaction of sodium or potassium molybdate and excess malic acid in a wide range of pH values (pH 4.0–7.0) resulted in the isolation of two cis-dioxo-bis(malato)-Mo(VI) complexes, viz. Na₃[MoO₂H(S-mal)₂] and K₃[MoO₂H(S-mal)₂]·H₂O (H₃mal=malic acid). The sodium complex is also characterized by an X-ray structure analysis, showing that the mononuclear Mo units are linked together via very strong symmetric CO₂···H··· O₂C-hydrogen bond [2.432(5) Å], forming a polymeric chain. The molybdenum atoms are quasi-octahedrally coordinated by two cis-oxo groups and two bidentate malate ligands via its alkoxy and -carboxyl groups, while the β-carboxylic and carboxylate groups remain uncomplexed, as the coordination of vicinal carboxylate and alkoxide of homocitrate in FeMo cofactor of nitrogenase. The absolute configuration of the metal center in this S-malato complex is assigned as Λ and the homochirality within the chain is established as a homochiral form ···Λ_S–Λ_S–Λ_S–Λ_S···. It is proposed that the chiral configuration of the metal center in wild-type FeMo-co biosynthesis might be induced by the early coordination of the chiral R-homocitric acid, while a mixture of raceme might be obtained in the biosynthesis of NifV⁻ FeMo-cofactor. The absolute configuration of wild-type FeMo-cofactor is assigned as Δ_R.     

Assessing the absolute configuration of (7S,8R)-(−)-epoxyjasmone

The absolute configuration of cis-epoxyjasmone (−)-2, isolated from Trichosporum cutaneum CCT 1903 whole cells, has been unambiguously established as (7S,8R), [α]_D²⁰ −29.0° (c 1.3, CHCl₃), by a new two step method, using a regioselective epoxide opening as the key step followed by Mosher acid derivatization.     

A structural transition in egg lecithin-cholesterol bilayers at 12 °C

The thermal coefficient of expansion of egg lecithin bilayer thickness, αd₁, was measured as a function of its cholesterol content up to mole ratio lecithin/cholesterol of 1:1, and over the temperature range 0–40 °C. At all cholesterol contents αd₁ changes abruptly at approximately 12 °C indicating a structural transition at this temperature. Above 12 °C, αd₁ decreases monotonically from −2·10⁻³ for pure egg lecithin to −1·10^–3 at mole ratio 1:1. Below 12 °C αd₁ is walways higher than above 12 °C and shows a sharp, anomalously high value of −6·10⁻³ at the mole ratio 2:1. The results have been interpreted as the movement of cholesterol into the bilayer or the formation of lecithin-cholesterol “complexes” at temperatures below 12 °C. Similar studies with phosphatidylinositol containing cholesterol showed no structural transition and lysolecithin containing cholesterol behaved differently giving two lamellar phases in equilibrium.     

Characterization, size estimation and solubilization of α-macroglobulin complex receptors in liver membranes

Receptors for α₂-macroglobulin-proteinase complexes have been characterized in rat and human liver membranes. The affinity for binding of ¹²⁵I-labelled α₂-macroglobulin · trypsin to rat liver membranes was markedly pH-dependent in the physiological range with maximum binding at pH 7.8–9.0. The half-time for association was about 5 min at 37°C in contrast to about 5 h at 4°C. The half-saturation constant was about 100 pM at 4°C and 1 nM at 37°C (pH 7.8). The binding capacity was approx. 300 pmol per g protein for rat liver membranes and about 100 pmol per g for human membranes. Radiation inactivation studies showed a target size of 466 ± 71 kDa (S.D., n = 7) for α₂-macroglobulin · trypsin binding activity. Affinity cross-linking to rat and human membranes of ¹²⁵I-labelled rat α₁-inhibitor-3 · chymotrypsin, a 210 kDa analogue which binds to the α₂-macroglobulin receptors in hepatocytes (Gliemann, J. and Sottrup-Jensen, L. (1987) FEBS Lett. 221, 55–60), followed by SDS-polyacrylamide gel electrophoresis, revealed radioactivity in a band not distinguishable from that of cross-linked α₂-macroglobulin (720 kDa). This radioactivity was absent when membranes with bound ¹²⁵I-α₁-inhibitor-3 complex were treated with EDTA before cross-linking and when incubation and cross-linking were carried out in the presence of a saturating concentration of unlabelled complex. The saturable binding activity was maintained when membranes were solubilized in the detergent 3-[(3-cholamidopropyl)dimethylammonio]profane sulfonate (CHAPS) and the size of the receptor as estimated by cross-linking experiments was shown to be similar to that determined in the membranes. It is concluded that liver membranes contain high concentrations of an approx. 400–500 kDa α₂-macroglobulin receptor soluble in CHAPS. The soluble preparation should provide a suitable material for purification and further characterization of the receptor.     

Synthesis and biological activity of 17α-alkynylamide derivatives of estradiol

Seven estradiol (E₂) derivatives with an alkynylamide side chain at the 17α position were synthesized starting from ethynylestradiol (EE₂). The main chemical step was the coupling reaction of the acetylide ion of EE₂ with carbon dioxide, glutaric anhydride or bromoalkyl ortho ester. The synthesis of these compounds is fast (3–6 steps according to the compound) and is easily achieved with good yield. Five compounds with different side chain lenghts were evaluated for uterotrophic and antiuterotrophic activity in the CD-1 mouse. None of the tested compounds shows estrogenic activity in this sensitive in vitro system. At low doses (1 and 3 μg), a 14–57% inhibition of E₂-induced uterine growth was observed while no additional inhibition was observed at the 10, 20 and 30 μg doses. In human breast carcinoma cells in culture, all compounds show estrogenic activity at high concentrations while only compound 39 (N-buty,N-methyl-8-[3′,17′β-dihydroxy estra-1′,3′,5′(10′)-trien-17′α-yl]-7-octynamide) possesses antiproliferative or antiestrogenic effects. No significant correlation could be demonstrated between alkynylamide side chain length and estrogenic or antiestrogenic activity. Among the compounds tested, the derivative of EE₂ possessing a five-methylene (CH₂) side chain (compound 39) possesses the best antiestrogenic activity (44 ± 7% in the CD-1 mouse uterus assay at the 3μg dose and 57 ± 4% at 0.1 nM in human ZR-75-1 cancer cells in culture).     

Inter and intra-species-related differences in the regulation of the cardiac autonomic system

The heart rate response to isoproterenol (HR-Iso), density and affinity (k_d) of β-adrenergic (β-AR) and muscarinic (M₂) receptors were compared among three rodents with different generation-life histories of confinement and of high altitude exposure. The European guinea pig (Cavia porcellus) (EGp), a laboratory animal that arrived in Europe after the Spanish Conquest of South America and the Peruvian guinea pig (C. porcellus) (PGp), a semi-wild animal that came from the altiplano to sea level at least 25 generations ago, were used for intra-species comparison. Wistar rats (WR) were used for inter-species comparison as representative of a typical sea level laboratory animal. The HR-Iso was lower in EGp than in the PGp. The PGp showed the highest β-AR density (P<0.0005) and the highest β-AR k_d values (P<0.0005) when compared to both EGp and WR groups (β-AR B_max (fmol mg⁻¹ prot), WR, 19±4; Egp, 34±10; PGp, 74±15. β-AR k_d (pM), WR, 24±10; Egp, 17±7; PGp, 39±14). In contrast, PGp showed lower M₂ receptor density values than the EGp (P<0.0005). The WR had the highest M₂ receptor densities (M₂ B_max (fmol mg⁻¹ prot), WR, 188±15; Egp, 147±9; PGp, 118±6 and M₂ k_d (pM), WR, 65±12; Egp, 67±6; PGp, 92±2). The inter and intra-species differences found may be related to their respective history of confinement rather than to their history of exposure to high altitude.     

Characterization of galactomannans isolated from legume endosperms of Caesalpinioideae and Faboideae subfamilies by multidetection aqueous SEC

Galactomannans isolated from legume seed endosperms, including those of commercial interest, have been characterized by multidetection aqueous SEC. Galactomannans derived from seeds of the Faboideae subfamily had substantially higher M_w than those from Caesalpinioideae seeds (M_w,Fab = 2.4–3.1 × 10⁶ g/mol, M_w,Caes. = 0.86–2.1 × 10⁶ g/mol) and within the latter botanical subfamily, an apparent correlation between M_w and the degree of galactose substitution DG was found. The molar mass distributions were unimodal and differed primarily by a scale factor, with distributional widths narrower than a true Flory ‘most-probable distribution’; good fits to Schulz–Zimm model were obtained. Across subfamilies no differences were found in the exponents of [η]–M and R_v–M relationships (0.61 ± 0.02, 0.54 ± 0.01, respectively), the Flory chain stiffness ratio (C_∞ = 20 ± 1 (BSF analysis)), or the persistence length (L_p = 5.5 ± 0.2 nm) obtained from SEC fraction data. However, it was found that prefactors in the [η]–M and R_v–M relationships as well as the unperturbed parameter K_Θ decrease in proportion to DG and therefore chain density. Generalized relationships incorporating galactose-dependent prefactors were therefore developed to model SEC fraction data of native galactomannans ([η]_GM = (1800 ± 200) × M_o^−1.61 × M^0.61±0.02, R_v,GM = 0.63 ± 0.05 × M_o^−0.54 × M^0.54±0.01) as well as lower-M fractions obtained by ultrasonication ([η]_GM = (730 ± 100) × M_o^−1.71 × M_w^0.71±0.02, R_v,GM = 0.49 ± 0.05 × M_o^−0.57 × M_w^0.57±0.01, M ≈ 1 × 10⁵-native). As a consequence of this dependence and the observed patterns in molar mass variation, [η] varies within a narrow range for galactomannans as a whole despite substantial M_w differences.     

Preparation and characterization of some uranyl complexes of amino acids. The crystal structure of [UO2(γ-aminobutanoic acid)3] (NO3)2

Uranyl complexes of glycine, β-alanine and γ-aminobutanoic acid were prepared and characterized. All those studied or examined contain the aminoacids in the zwitterionic form binding the metal through the ionized carboxyl group. The structure of the title compound was determined by X-ray crystallography and refined to R=6.6%. The crystals are triclinic, space group P1, Z = 2, with a = 11.966(5), b = 12.054(5), c = 10.581(5) Å, α = 70.88(3)°, β = 109.89(3)°, and γ = 120.72(3)°. The uranyl group is equatorially bonded to the bidentate carboxylate of three molecules of the organic ligand forming a distorted hexagonal bipyramidal coordination geometry around the metal. U---O(equatorial) distances are in the range 2.24–2.48 Å.     

Kinetics and mechanism of CO substitution of [η-CpFe(CO)3]PF6 with PPh3 in the presence of substituted pyridine N-oxide

The kinetics of substitution reactions of [η-CpFe(CO)₃]PF₆ with PPh₃ in the presence of R-PyOs have been studied. For all the R-PyOs (R = 4-OMe, 4-Me, 3,4-(CH)₄, 4-Ph, 3-Me, 2,3-(CH)₄, 2,6-Me₂, 2-Me), the reactions yeild the same product [η⁵-CpFe(CO)₂PPh₃]PF₆, according to a second-order rate law that is first order in concentrations of [η⁵-CpFe(CO)₃]PF₆ and of R-PyO but zero order in PPh₃ concentration. These results, along with the dependence of the reaction rate on the nature of R-PyO, are consistent with an associative mechanism. Activation parameters further support the bimmolecular nature of the reactions: ΔH^≠ = 13.4 ± 0.4 kcal mol⁻¹, ΔS^≠ = −19.1 ± 1.3 cal k⁻¹ mol⁻¹ for 4-PhPyO; ΔH^≠ = 12.3 ± 0.3 kcal mol⁻¹, ΔS^≠ = 24.7 ±1.0 cal K⁻¹ mol⁻¹ for 2-MePyO. For the various substituted pyridine N-oxides studied in this paper, the rates of reaction increase with the increasing electron-donating abilities of the substituents on the pyridine ring or N-oxide basicities, but decrease with increasing ¹⁷O chemical shifts of the N-oxides. Electronic and steric factors contributing to the reactivity of pyridine N-oxides have been quantitatively assessed.     

Influence of chelators and iron ions on the production and degradation of H2O2 by β-amyloid–copper complexes

β-Amyloid peptide (Aβ) 1–42, involved in the pathogenesis of Alzheimer’s disease, binds copper ions to form Aβ · Cu_n complexes that are able to generate H₂O₂ in the presence of a reductant and O₂. The production of H₂O₂ can be stopped with chelators. More reactive than H₂O₂ itself, hydroxyl radicals HO (generated when a reduced redox active metal complex interacts with H₂O₂) are also probably involved in the oxidative stress that creates brain damage during the disease. We report in the present work a method to monitor the effect of chelating agents on the production of hydrogen peroxide by metallo-amyloid peptides. The addition of H₂O₂ associated to a pre-incubation step between ascorbate and Aβ · Cu_n allows to study the formation of H₂O₂ but also, at the same time, its transformation by the copper complexes. Aβ · Cu_n peptides produce but do not efficiently degrade H₂O₂. The reported analytic method, associated to precipitation experiments of copper-containing amyloid peptides, allows to study the inhibition of H₂O₂ production by chelators. The action of a ligand such as EDTA is probably due to the removal of the copper ions from Aβ · Cu_n, whereas bidentate ligands such as 8-hydroxyquinolines probably act via the formation of ternary complexes with Aβ · Cu_n. The redox activity of these bidentate ligands can be modulated by the incorporation or the modification of substituents on the quinoline heterocycle.     

Crystal structures of cyclomaltohexaose (α-cyclodextrin) complexes with p-chlorophenol and p-cresol

Crystal structures of cyclomaltohexaose (α-cyclodextrin) complexes with p-chlorophenol and p-cresol have been determined by single-crystal X-ray diffraction studies. The space group of the α-cyclodextrin–p-chlorophenol complex is P2₁2₁2₁ with unit cell dimensions of a=15.299(3), b=24.795(5), c=13.447(5) Å, and that of the α-cyclodextrin–p-cresol complex is P2₁ with unit cell dimensions of a=7.927(7), b=13.568(7), c=24.54(1) Å, β=90.41(8)°. In spite of the similar structures of guest molecules, both complexes have different inclusion modes and packing structures.     

Preparation, X-ray structure and solution behavior of [Ag(9-EtGH-N7)2]NO3·H2O (9-EtGH=9-ethylguanine)

The preparation and X-ray structure of [Ag(9-EtGH-N7)₂]NO₃·H₂O(9-EtGH=neutral 9-ethylguanine) is reported. The compound crystallizes in the triclinic system, space group P with a=7.063(6), b=7.153(3), c=11.306(10) Å, α=83.36(6), β=76.66(7), γ=81.44(6)°. The cation is centrosymmetric with Ag(I) coordinated via two N7 positions and Ag---N7 bond lengths of 2.11(1) Å. Applying ¹⁰⁹Ag NMR spectroscopy, complex formation constants for both the 1:1 complex (log β₁=0.6) and the title compound (log β₂=1.6) in Me₂SO have been determined.     

The inducible and cytochrome P450-containing dehydroepiandrosterone 7α-hydroxylating enzyme system of Fusarium moniliforme

7α-Hydroxylation of DHEA by Fusarium moniliforme was investigated with regard to inducibility and characterization of the responsible enzyme system. Using GC/MS, the 7-hydroxylated metabolites of DHEA produced after biotransformation by Fusarium moniliforme mycelia were identified. The strain of Fusarium moniliforme hydroxylated DHEA predominantly at the 7α-position, with minor hydroxylation occurring at the 7β-position. Constitutive 7α-hydroxylation activity was low, but DHEA induced the enzyme complex responsible for 7α-hydroxylation via an increase in protein synthesis. DHEA 7α-hydroxylase was found to be mainly microsomal, and the best production yields of 7α-hydroxy-DHEA (28.5 ± 3.51 pmol/min/mg protein) were obtained with microsomes prepared from 18-h-induced mycelia. Kinetic parameters (K_M=1.18 ± 0.035 μM and V_max=909 ± 27 pmol/min/mg protein) were determined. Carbon monoxide inhibited 7α-hydroxylation of DHEA by microsomes of Fusarium moniliforme. Also, exposure of mycelia to DHEA increased microsomal P450 content. These results demonstrated that: (i) DHEA is 7α-hydroxylated by microsomes of Fusarium moniliforme; (ii) DHEA induces Fusarium moniliforme 7α-hydroxylase; (iii) this enzyme complex contains a cytochrome P450.     

A spectroscopic model for the high pH form of sulfite oxidase

The syntheses and spectroscopic properties of two monomeric oxo-Mo(V) complexes [NMe₄][MoO(SC₆H₄---CH=N---C₆H₄O)(SAr)₂] (Ar=Ph (2a), PhCH₃ (2b)) exhibiting a novel S₃NO coordination site are described. The EPR parameters of the Mo(V) complexes are almost identical with the parameters for the high pH form of sulfite oxidase, allowing further predictions for the unknown coordination site of the molybdenum cofactor in such molybdenum-containing enzymes. The Mo(V) compounds react with water to form a μ-oxo-bridged Mo(V) dimer, which is readily oxidized by oxygen to give the monomeric dioxo-Mo(VI) complex MoO₂(SC₆H₄---CH=N---C₆H₄O)(sol) (4) (sol=acetonitrile; dimethyl sulfoxide (DMSO)). The structure of 4 has been determined by X-ray crystallography (space group P (No. 2), a=7.855(4), b=9.530(3), c=11.676(6) Å, α=103.96(3), β=99.03(3), γ=100.73(3)°, V=814.5 ų, ρ_calc=1.79 g cm⁻³, Z=2, R(F)=0.026, R(wF)=0.026). The geometry about the molybdenum is distorted octahedral, with two terminal oxo groups cis to each other.     

Highly sensitive determination of N-terminal prolyl dipeptides, proline and hydroxyproline in urine by high-performance liquid chromatography using a new fluorescent labelling reagent, 4-(5,6-dimethoxy-2-phthalimidinyl)-2-methoxyphenylsulfonyl chloride

A highly sensitive pre-column HPLC method for simultaneous determination of prolyl dipeptides, Pro and Hyp in urine was developed. The analytes were labelled with 4-(5,6-dimethoxy-2-phthalimidinyl)-2-methoxyphenylsulfonyl chloride at 70°C for 20 min. The derivatives separated on tandem reversed-phase columns by a gradient elution and were monitored with fluorescence detection at 318 nm (excitation) and 392 nm (emission). The detection limits for prolyl dipeptides, Pro and Hyp were 1–5 fmol/injection (S/N=3). Urine samples were treated with o-phthalaldehyde, followed by purification on a Bond Elut C₁₈ column before conducting the labelling reaction. Pro–Hyp, Pro–Gly and Pro–Pro were identified as prolyl dipeptides in urine. The within-day and between-day relative standard deviations were 1.5–4.8 and 1.7–5.8%, respectively. The concentrations of Pro–Hyp, Pro–Gly, Pro–Pro, Pro and Hyp in normal human urine were 97.6±28.2, 2.74±1.48, 2.08±1.13, 6.71±3.34 and 2.30±1.59 nmol/mg creatinine, respectively.     

Single crystals of dextran: High temperature polymorph

Lamellar single crystals of a high temperature polymorph of synthetic dextran were prepared at temperatures ranging from 120 to 200°C in a mixture of water and polyethylene glycol. Individual crystals with lath-like shapes gave well resolved electron diffraction diagrams from which the reciprocal unit cell parameters a^*, b^* and γ^* could be measured. The direct cell parameters were then determined from a series of electron diffraction diagrams obtained by sequential tilting of the crystal about the b^* axis. This gave a = 0·922 ± 0·001 nm, b = 0·922 ± 0·001 nm, c (chain axis) = 0·78 ± 0·01 nm, α = γ = 90° and β = 91·3° ± 0·5°. The crystal symmetry was P2₁ with b as the unique monoclinic axis. These data coupled with the observed density of the crystals, indicated that the unit cell contained two antiparallel dextran chains of two residues each. When the crystals were grown at temperatures between 90 and 120°C, a percentage of crystals containing both low and high temperature polymorphs were obtained. These mixed crystals had most likely grown in syntaxy.     

Purification and characterisation of the cardenolide-specificβ-glucohydrolase CGH II from Digitalis lanata leaves

A cardenolide-hydrolysing β-D-glucosidase was isolated from young leaves of Digitalis lanata. Since this enzyme differs from the cardenolide glucohydrolase (CGH) described and characterised previously, it was termed cardenolide glucohydrolase II (CGH II). CGH II was detected in various Digitalis tissue cultures as well as in young leaves of D. lanata. The latter source was used as the starting material for the isolation and purification of CGH II. The specific enzyme activity reached about 15 pkat·mg^–1 protein in buffered leaf extracts. Optimal CGH II activity was seen at around pH 6.0 and 50 °C. CGH II was purified about 600-fold by anion exchange chromatography, size exclusion chromatography and hydroxyapatite chromatography. The apparent molecular mass of CGH II was 65 kDa as determined by SDS-PAGE. CGH II exhibited a high substrate specificity towards cardenolide disaccharides, especially to those with a 1-4-β-linked glucose-digitoxose moiety such as glucoevatromonoside. The K_m- and V_max-values for this particular substrate were calculated to be 101 μM and 19.8 nkat·mg^–1 protein, respectively.     

Fasting metabolism in Antarctic fur seal (Arctocephalus gazella) pups

The metabolism of 52–73-day old Antarctic fur seal pups from Bird Island, South Georgia, was investigated during fasting periods of normal duration while their mothers were at sea foraging. Body mass decreased exponentially with pups losing 3.5–3.8% of body mass per day. Resting metabolic rate also decreased exponentially from 172–197 ml (O₂)·min⁻¹ at the beginning of the fast and scaled to M_b^0.74 at 2.3 times the level predicted for adult terrestrial mammals of similar size. While there was no significant sex difference in RMR, female pups had significantly higher (F_1,18=6.614, P<0.019) mass-specific RMR than male pups throughout the fasting period. Fasting FMR was also significantly (t₁₅=2.37, P<0.035) greater in females (823 kJ·kg⁻¹·d⁻¹) than males (686 kJ·kg⁻¹·d⁻¹). Average protein turnover during the study period was 19.3 g·d⁻¹ and contributed to 5.4% of total energy expenditure, indicating the adoption of a protein-sparing strategy with a reliance on primarily lipid catabolism for metabolic energy. This is supported by observed decreases in plasma BUN, U/C, glucose and triglyceride concentrations, and an increase in β-HBA concentration, indicating that Antarctic fur seals pups adopt this strategy within 2–3 days of fasting. Mean RQ also decreased from 0.77 to 0.72 within 3 days of fasting, further supporting a rapid commencement of protein-sparing. However, RQ gradually increased thereafter to 0.77, suggesting a resumption of protein catabolism which was not substantiated by changes in plasma metabolites. Female pups had higher TBL (%) than males for any given mass, which is consistent with previous findings in this and other fur seal species, and suggests sex differences in metabolic fuel use. The observed changes in plasma metabolites and protein turnover, however, do not support this.     

Binding of estrogens by α-fetoprotein in rat amniotic fluid

Amniotic fluid from 15–17-day rat fetuses bound estrone and 17β-estradiol specifically. Related steroids such as estriol, 6-ketoestradiol, 17α-estradiol and testosterone were not bound to any significant extent. The apparent K_a for 17β-estradiol was 2.6·10⁸ M⁻ at 4°C; 6 nmoles of 17β-estradiol were bound per ml of amniotic fluid. The binding component appears to be α-fetoprotein in that it migrates as an α₁-globulin upon polyacrylamide gel electrophoresis and has an isoelectric pH of 4.7 as determined by isoelectric focusing. Furthermore, binding activity was precipitated by antiserum which was shown by immuno-electrophoresis to be specific for α-fetoprotein. Binding activity, partially purified by isoelectric focusing of amniotic fluid, was associated with one of two bands seen by polyacrylamide gel electrophoresis. This band migrated as an α₁-globulin.     

Macromolecular conformation of chitosan in dilute solution: A new global hydrodynamic approach

Chitosans of different molar masses were prepared by storing freshly prepared samples for up to 6 months at either 4, 25 or 40 °C. The weight-average molar masses, M_w and intrinsic viscosities, [η] were then measured using size exclusion chromatography coupled to multi-angle laser light scattering (SEC-MALLS) and a “rolling ball” viscometer, respectively.The solution conformation of chitosan was then estimated from:

(a) the Mark–Houwink–Kuhn–Sakurada (MHKS) power law relationship [η] = kM_w^a and

(b) the persistence length, L_p calculated from a new approach based on equivalent radii [Ortega, A., & Garcia de la Torre, J. (2007). Equivalent radii and ratios of radii from solution properties as indicators of macromolecular conformation, shape, and flexibility. Biomacromolecules, 8, 2464–2475].

Both the MHKS power law exponent (a = 0.95 ± 0.01) and the persistence length (L_p = 16 ± 2 nm) are consistent with a semi-flexible rod type (or stiff coil) conformation for all 33 chitosans studied. A semi-flexible rod conformation was further supported by the Wales–van Holde ratio, the translational frictional ratio and sedimentation conformation zoning.