Interactions Between Peptide and Preservatives: Effects on Peptide Self-Interactions and Antimicrobial Efficiency In Aqueous Multi-Dose Formulations.

PURPOSE: Antimicrobial preservatives are known to interact with proteins and potentially affect their stability in aqueous solutions. In this systematic study, the interactions of a model peptide with three commonly used preservatives, benzyl alcohol, phenol and m-cresol, were evaluated. METHODS: The impact on peptide oligomerization was studied using GC-MALS, SEC-MALS and DLS, antimicrobial efficiency of different formulations were studied using the Ph. Eur. antimicrobial efficacy test, and the molecular adsorption of preservative molecules on reversible peptide oligomers was monitored using NMR. RESULTS: The hydrodynamic radius and molar mass of the peptide oligomers was shown to clearly increase in the presence of m-cresol but less significantly with phenol and benzyl alcohol. The increase in size was most likely caused by peptide self-interactions becoming more attractive, leading to reversible oligomerization. On the other hand, increasing the concentration of peptide in multi-dose formulations led to reduced molecular mobility and decreased antimicrobial efficacy of all preservatives. CONCLUSIONS: Peptide-preservative interactions not only affect peptide self-interactions, but also antimicrobial efficiency of the preservatives and are thus of significant relevance. Adsorption of preservatives on oligomeric states of peptides is proposed as a mechanism to explain this reduced antimicrobial efficacy.

New Processes for Freeze-Drying in Dual-Chamber Systems.

Dual-chamber systems can offer self-administration and home care use for lyophilized biologics. Only a few products have been launched in dual-chamber systems so far-presumably due to dual-chamber systems' complex and costly drug product manufacturing process. Within this paper, two improved processes (both based on tray filling technology) for freeze-drying pharmaceuticals in dual-chamber systems are described. Challenges with regards to heat transfer were tackled by (1) performing the freeze-drying step in a needle-down orientation in combination with an aluminum block, or (2) freeze-drying the drug product "externally" in a metal cartridge with subsequent filling of the lyophilized cake into the dual-chamber system. Metal-mediated heat transfer was shown to be efficient in both cases and batch (unit-to-unit) homogeneity with regards to sublimation rate was increased. It was difficult to influence ice crystal size using different methods when in use with an aluminum block due to its heat capacity. Using such a metal carrier implies a large heat capacity leading to relatively small ice crystals. Compared to the established process, drying times were reduced by half using the new processes. The drying time was, however, longer for syringes compared to vials due to the syringe design (long and slim). The differences in drying times were less pronounced for aggressive drying cycles. The proposed processes may help to considerably decrease investment costs into dual-chamber system fill-finish equipment. LAY ABSTRACT: Dual-chamber syringes offer self-administration and home care use for freeze-dried pharmaceuticals. Only a few products have been launched in dual-chamber syringes so far-presumably due to their complex and costly drug product manufacturing process. In this paper two improved processes for freeze-drying pharmaceuticals in dual-chamber syringes are described. The major challenge of freeze-drying is to transfer heat through a vacuum. The proposed processes cope with this challenge by (1) freeze-drying the drug product in the syringe in an orientation in which the product is closest to the heat source, or (2) freeze-drying the drug product outside the syringe in a metal tube. The latter requires filling the freeze-dried product subsequently into the dual-chamber syringe. Both processes were very efficient and promised to achieve similar freeze-drying conditions for all dual-chamber syringes within one production run. The proposed processes may help to considerably decrease investment costs into dual-chamber syringe fill-finish equipment.

DNA oxidation products determined with repair endonucleases in mammalian cells: types, basal levels and influence of cell proliferation.

Purified repair endonucleases such as Fpg protein, endonuclease III and IV allow a very sensitive quantification of various types of oxidative DNA modifications in mammalian cells. By means of these assays, the numbers of base modifications sensitive to Fpg protein, which include 8-hydroxyguanine (8-oxoG), were determined to be less than 0.3 per 10(6) bp in several types of untreated cultured mammalian cells and human lymphocytes and less than 10 per 10(6) bp in mitochondrial DNA from rat and porcine liver. Oxidative 5,6-dihydropyrimidine derivatives sensitive to endonuclease III and sites of base loss sensitive to endonuclease IV or exonuclease III were much less frequent than Fpg-sensitive modifications. Here, we summarize our indications that all Fpg-sensitive modifications are recognized under the assay conditions and that on the other hand there is no artifactual generation of oxidative damage during the analysis. In addition, we show that the steady-state levels of Fpg-sensitive modifications in human lymphocytes and in two mammalian cell lines were higher in proliferating than in resting (confluent) cells. Only some of the Fpg-sensitive base modifications induced by various oxidants are 8-oxoG residues, as demonstrated for the damage under cell-free conditions. The percentage was dependent on the species ultimately responsible for the DNA damage and was approx. 40% in the case of hydroxyl radicals and peroxynitrite, 75% for type II photosensitizers (reacting via singlet oxygen) and only 20-30% in the case of type I photosensitizers such as riboflavin and acridine orange, which are assumed to react directly with the DNA.

Oxidative DNA base damage induced by singlet oxygen and photosensitization: recognition by repair endonucleases and mutagenicity.

We have analyzed the recognition by various repair endonucleases of DNA base modifications induced by three oxidants, viz. [4-(tert-butyldioxycarbonyl)benzyl]triethylammonium chloride (BCBT), a photochemical source of tert-butoxyl radicals, disodium salt of 1,4-etheno-2,3-benzodioxin-1,4-dipropanoic acid (NDPO(2)), a chemical source of singlet oxygen, and riboflavin, a type-I photosensitizer. The base modifications induced by BCBT, which were previously shown to be mostly 7,8-dihydro-8-oxoguanine (8-oxoGua) residues, were recognized by Fpg and Ogg1 proteins, but not by endonuclease IIII, Ntg1 and Ntg2 proteins. In the case of singlet oxygen induced damage, 8-oxoGua accounted for only 35% of the base modifications recognized by Fpg protein. The remaining Fpg-sensitive modifications were not recognized by Ogg1 protein and relatively poor by endonuclease III, but they were relatively good substrates of Ntg1 and Ntg2. In the case of the damage induced by photoexcited riboflavin, the fraction of Fpg-sensitive base modifications identified as 8-oxoGua was only 23%. In contrast to the damage induced by singlet oxygen, the remaining lesions were not only recognized by Ntg1 and Ntg2 proteins and (relatively poor) by endonuclease III, but also by Ogg1 protein. The analysis of the mutations observed after transfection of modified plasmid pSV2gpt into Escherichia coli revealed that all agents induced near exclusively GC-->TA and GC-->CG transversions, the numbers of which were correlated with the numbers of 8-oxoGua residues and Ntg-sensitive modifications, respectively. In conclusion, both singlet oxygen and the type-I photosensitizer riboflavin induce predominantly oxidative guanine modifications other than 8-oxoGua, which most probably give rise to GC-->CG transversions and in which eukaryotic cells are substrates of Ntg1 and Ntg2 proteins.

Oxidative DNA damage and mutations induced by a polar photosensitizer, Ro19-8022.

The oxidative DNA damage induced by the polar photosensitizer Ro19-8022 in the presence of light was studied and correlated with the associated mutagenicity. Both in isolated DNA and AS52 Chinese hamster ovary cells, photoexcited Ro19-8022 gave rise to a DNA damage profile that was similar to that caused by singlet oxygen: base modifications sensitive to the repair endonuclease Fpg protein, which according to high-performance liquid chromatography (HPLC) analysis were predominantly 8-hydroxyguanine (8-oxoG) residues, were generated in much higher yield than single-strand breaks, sites of base loss (AP sites) and oxidative pyrimidine modifications sensitive to endonuclease III. Fifty percent of the Fpg-sensitive modifications were repaired within 2 h. Under conditions that induced 10 Fpg-sensitive modifications per 10(6) bp (six 8-oxoG residues per 10(6) bp), approximately 60 mutations per 10(6) cells were induced in the gpt locus of the AS52 cells. A rather similar mutation frequency was observed when a plasmid carrying the gpt gene was exposed to Ro19-8022 plus light under cell-free conditions and subsequently replicated in bacteria. Sequence analysis revealed that GC-->TA and GC-->CG transversions accounted for 90% of the base substitutions. A significant generation of micronuclei was detectable in AS52 cells exposed to the photosensitizer plus light as well.

tert-Butoxyl radicals generate mainly 7,8-dihydro-8-oxoguanine in DNA.

Like hydroxyl radicals, alkoxyl radicals have been implicated in the generation of cellular oxidative DNA damage under physiological conditions; however, their genotoxic potential has not yet been established. We have analyzed the DNA damage induced by a photochemical source of tert-butoxyl radicals, the water soluble peroxy ester [4-(tert-butyldioxycarbonyl)benzyl]triethylammonium chloride (BCBT), using various repair endonucleases as probes. The irradiation (UV(360)) of BCBT in the presence of bacteriophage PM2 DNA was found to generate a DNA damage profile that consisted mostly of base modifications sensitive to the repair endonuclease Fpg protein. Approximately 90% of the modifications were identified as 7,8-dihydro-8-oxoguanine (8-oxoGua) residues by HPLC/ECD analysis. Oxidative pyrimidine modifications (sensitive to endonuclease III), sites of base loss (AP sites) and single-strand breaks were only minor modifications. Experiments with various scavengers and quenchers indicated that the DNA damage by BCBT+UV(360) was caused by tert-butoxyl radicals as the ultimate reactive species. The mutagenicity associated with the induced damage was analyzed in the gpt gene of plasmid pSV2gpt, which was exposed to BCBT+UV(360) and subsequently transfected into Escherichia coli. The results were in agreement with the specific generation of 8-oxoGua. Nearly all point mutations (20 out of 21) were found to be GC-->TA transversions known to be characteristic for 8-oxoGua. In conclusion, alkoxyl radicals generated from BCBT+UV(360) induce 8-oxoGua in DNA with a higher selectivity than any other reactive oxygen species analyzed so far.

Influence of glutathione levels and heat-shock on the steady-state levels of oxidative DNA base modifications in mammalian cells.

The effects of thiols, ascorbic acid and thermal stress on the basal (steady-state) levels of oxidative DNA base modifications were studied. In various types of untreated cultured mammalian cells, the levels of total glutathione were found to be inversely correlated with the levels of DNA base modifications sensitive to the repair endonuclease Fpg protein, which include 8-hydroxyguanine (8-oxoG). A depletion of glutathione by treatment with buthionine sulphoximine increased the steady-state level in AS52 Chinese hamster cells by approximately 50%. However, additional thiols in the culture medium did not reduce the level of Fpg-sensitive base modifications: 0-10 mM N-acetylcysteine had no effect, whereas cysteine ethylester even increased the oxidative DNA damage at concentrations >0.1 mM. Similarly, ascorbic acid (0-20 mM) failed to reduce the steady-state levels. When AS52 cells were grown at elevated temperature (41 degrees C), the steady-state level of the oxidative DNA modifications increased by 40%, in spite of a concomitant 1.6-fold increase of the cellular level of total glutathione. Depletion of glutathione at 41 degrees C nearly doubled the already elevated level of oxidative damage. A constitutive expression of the heat-shock protein Hsp27 in L929 mouse fibrosarcoma cells at 37 degrees C increased the glutathione level by 60%, but had little effect on the level of oxidative DNA damage.