Partial synthesis and properties of des-A1-glycine-insulin (author's transl)]

Des-Gly-A-chain-tetra-S-sulphonate was prepared by Edman degradation following two different routes. A) Via complete reaction of A-chain from bovine insulin with 150 equivalents of phenylisothiocyanate in pyridine/water and trifluoroacetic acid cleavage of the resulting phenylthiocarbamoyl A-chain. B) Via reaction of bovine insulin with about 20 equivalents of phenylisothiocyanate until a substitution degree of 2.3-2.5 was reached, trifluoroacetic acid cleavage of the crude derivatives and oxidative sulphitolysis of the resulting desaminoacyl insulins. Preparative electrophoresis (pH 2) or ion exchange chromatography using DEAE-Sephadex gave des-Gly-A-chain in a yield of 60-65% of theory according to method B, containing less than 1% of glycine. Des-GlyA1-insulin was prepared by combination with 0.67 equivalents of B-chain-bis-S-sulphonate and isolated in yields of 5-13%, based on B-chain, after gel filtration (pH 8) and ion exchange chromatography (CM-cellulose, pH 3-2). The electrophoretically (pH 2 and 8.6) homogeneous analogue did not crystallize in the presence of zinc ions. Its blood sugar lowering potency is 10-25%, its in vitro insulin activity (fat cell assay) only 1-2%. The immunoreactivity against anti-insulin sera in different test systems is markedly reduced. There are clear differences between the CD-spectra of des-Gly-insulin and insulin, indicating a loss of ordered secondary structure. From the results it is concluded that structure-stabilizing non covalent bonds are abolished by the removal of the invariant A1-glycine. This leads to conformational alterations which cause the far-going inactivation of the molecule.     

Semisynthetic sheep des-A1-glycine insulin (author's transl)]

The synthetic Des-1-glycine-A-chain of sheep insulin as the monomeric cyclic bisdisulfide and native bovine B-chain bissulfonate were reduced together with mercaptoethanol. They combined at pH 10.6 to yield Des-A1-glycine-insulin. This was purified by gel and ion exchange chromatography. The low insulin activity (0.4 - 0.6%) as measured by the fat cell test as well as the change in the CD spectrum indicated that the loss of the N-terminal glycine of the A-chain results in fully inactive insulin. This confirms the results obtained earlier by partial synthesis of Des-A1-glycine-insulin.     

Aggregation of sponge cells : XIV. Possible substitution of calcium ions by polycations

Single cells from the siliceous sponge Geodia cydonium, obtained after chemical dissociation, reaggregate in the presence of the aggregation factor in Ca2+-containing medium to large aggregates. It was found that polyvalent organic cations (polylysine, spermine, spermidine, putrescine) enhance the Ca2+-mediated cell aggregation. In Ca2+-free medium these compounds also cause reaggregation; aggregates of a diameter up to 800 micron are formed within 120 min. Proteins, containing basic groups of amino acid residues have no influence on cell aggregation. Monovalent cations inhibit the reaggregation process. The enhancing effect of polyvalent organic cations on cell aggregation is dependent on the presence of the soluble aggregation factor. From the findings that polycations do not alter the duration of the lag phase (a characteristic of the aggregation factor-mediated Geodia cell reaggregation) and act in cooperation with the aggregation receptor, we assume that the polycations bind between the aggregation factor and the aggregation receptor.     

A rapid separation of the four major deoxynucleosides and deoxyinosine by high-pressure liquid cation-exchange chromatography

A simple, rapid, and sensitive method for the measurement of DNA, RNA, and protein synthesis in cell samples is presented. The method measures the amount of isotope incorporated into these macromolecules after cell collection on filter paper and washing with a methanol:chloroform:water mixture. Samples as low as 50 μg in size can be prepared in less than 30 sec for measurement of radioactivity.     

The effect of benzo[a]pyrene on sponges as model organisms in marine pollution

The majority of the investigations were performed with the marine sponge Tethya lyncurium at concentrations of 2 X 10(-8) to 1 X 10(-11) g/ml of benzo[a]pyrene (BaP). Sea-pollution was characterized as BaP equivalent activity in the Ames test. Increased activity of ornithine decarboxylase (ODC) was observed when sponges were artificially exposed at polluted marine areas for 3 weeks. In contrast to the situation in higher animals no ODC induction of the fast type was observed. Mixed function oxygenases (MFO) were not detected in sponges nor could they be induced as in vertebrates. BaP was absorbed by Tethya and concentrated 30--60-fold. In live, but not dead, artificially perfused sponges [3H]- and [14C]BaP-radiolabeled became firmly associated with DNA, RNA and protein of the sponges. The association persisted in isolated fractions, in nucleotides, in nucleosides and in protein hydrolysates. The BaP binding ratio to DNA was found to be strongly correlated to the concentration of BaP. Light modifies BaP and thus enables binding. In the dark only very low association, if any, is observed. The possible consequences of these findings are discussed.     

Cytochrome c peroxidase from Methylococcus capsulatus Bath

A bacterial cytochrome c peroxidase was purified from the obligate methanotroph Methylococcus capsulatus Bath in either the fully oxidized or the half reduced form depending on the purification procedure. The cytochrome was a homo-dimer with a subunit mol mass of 35.8 kDa and an isoelectric point of 4.5. At physiological temperatures, the enzyme contained one high-spin, low-potential (E _m7 = –254 mV) and one low-spin, high-potential (E _m7 = +432 mM ) heme. The low-potential heme center exhibited a spin-state transition from the penta-coordinated, high-spin configuration to a low-spin configuration upon cooling the enzyme to cryogenic temperatures. Using M. capsulatus Bath ferrocytochrome c ₅₅₅ as the electron donor, the K _M and V _max for peroxide reduction were 510 ± 100 nM and 425 ± 22 mol ferrocytochrome c ₅₅₅ oxidized min^–1 (mole cytochrome c peroxidase)^–1, respectively. Received: 6 January 1997 / Accepted: 27 May 1997