Sterilization of a new medical device using broad-spectrum pulsed light.

In the development of implantable medical devices, effective sterilization is an essential design element. This article outlines how broad-spectrum pulsed light (BSPL) has been implemented to sterilize a novel, implantable medical device. Components of the device have properties incompatible with most sterilization techniques. The unique characteristics of the device and sterilization method are described. Results are presented that show BSPL can be an effective sterilization method that has the potential to meet validation requirements to allow parametric release of the treated product.

Investigation of osmotically stable spheroplasts from two strains of Escherichia coli ML-35, W7-M5.

Osmotically stable spheroplasts were produced from Escherichia coli ML-35 and W7-M5 using either 1 min exposure to polymyxin B or 10 min exposure to Tris/EDTA, followed by 1 to 3 h incubation with lysozyme. Spheroplast membrane permeability studies were conducted using paired radioactive probes with E. coli ML-35. Experiments with 14C-sucrose-16 kD 3H-dextran indicated that the outer membrane had lost its barrier to 16 kD dextran. Parallel experiments with 81 kD 3H-dextran indicated that the outer membrane was impermeable to the larger dextran. EDTA treated cells also showed outer membrane permeability to 16 kD dextran. Cytoplasmic membrane integrity was confirmed using 14C-sucrose and 3H2O before and after exposure to polymyxin B and EDTA. Scanning electron microscopy showed that a rough surface on polymyxin B produced spheroplasts while Tris/EDTA spheroplasts showed the same smooth surface as control cells.

Calcium inhibition of efrotomycin production by Nocardia lactamdurans.

Efrotomycin is a modified polyketide antibiotic of the elfamycin family that has use in the area of pig husbandry. Optimization of the fermentation medium for production of efrotomycin by Nocardia lactamdurans revealed that the fermentation is sensitive to hard water and certain lots of cottonseed flour used to prepare a complex fermentation medium. A limited metal ion analysis of the hard water indicated that calcium ions are present at concentrations found to be inhibitory by the addition of calcium chloride to medium prepared with distilled water. Similarly, a correlation between lots of cottonseed flour that poorly supported the fermentation and high calcium levels is presented. Further experimentation revealed that by altering the sterilization conditions of the cottonseed flour, the inhibitory effect of poor lots could be prevented.

Retardation of folding as a possible means of suppression of a mutation in the leader sequence of an exported protein.

We have proposed (Randall, L. L., and Hardy, S. J. S. (1986) Cell 46, 921-928) that during export of protein from Escherichia coli, there is a kinetic partitioning between the pathway that leads to productive translocation and the pathway that leads to folding of precursors into a stable conformation that is incompatible with export. This model predicts that a decrease in rate along the productive pathway resulting from a defect in the leader sequence could be partially overcome by slowing the folding of the precursor and thereby increasing the time during which that polypeptide would be competent to enter the export pathway. Here it is shown that a change in the mature portion of maltose-binding protein that is known to suppress a mutation in the leader sequence (Cover, W. H., Ryan, J. P., Bassford, P. J., Jr., Walsh, K. A., Bollinger, J., and Randall, L. L. (1987) J. Bacteriol. 169, 1794-1800) also decreases the rate of folding of the precursor.

Modulation of folding pathways of exported proteins by the leader sequence.

Leader peptides that function to direct export of proteins through membranes have some common features but exhibit a remarkable sequence diversity. Thus there is some question whether leader peptides exert their function through conventional stereospecific protein-protein interaction. Here it is shown that the leader peptides retarded the folding of precursor maltose-binding protein and ribose-binding protein from Escherichia coli. This kinetic effect may be crucial in allowing precursors to enter the export pathway.

Suppression of a signal sequence mutation by an amino acid substitution in the mature portion of the maltose-binding protein.

An unusual spontaneous pseudorevertant of an Escherichia coli strain carrying the signal sequence point mutation malE14-1 was characterized. The suppressor mutation, malE2261, resulted in a single substitution of an aspartyl residue for a tyrosyl residue at position 283 in the sequence of the mature maltose-binding protein. The precursor retained the malE14-1 point mutation in the signal sequence. The pseudorevertant carrying both malE14-1 and malE2261 exported twice the amount of maltose-binding protein as that of the mutant carrying the malE14-1 allele alone but only 18% of the amount exported by a strain producing wild-type maltose-binding protein. A strain carrying the suppressor allele malE2261 in combination with a wild-type signal sequence exported normal quantities of maltose-binding protein to the periplasm. Mature MalE2261 had a Kd for maltose of 27 microM, compared with 3.6 microM for mature wild-type maltose-binding protein. The precursor species than contained both changes resulting from malE14-1 and malE2261 was significantly less stable in the cytoplasm than was the precursor containing only the change encoded by malE14-1.

Bdellovibrio bacteriovorus synthesizes an OmpF-like outer membrane protein during both axenic and intraperiplasmic growth.

Outer membrane preparations of Bdellovibrio bacteriovorus grown intraperiplasmically on Escherichia coli containing OmpF were prepared by the Triton X-100 procedure of Schnaitman (J. Bacteriol. 108:545-552, 1971). They contained a protein that migrated to almost the same position as E. coli OmpF in sodium dodecyl sulfate-acrylamide gradient gel electrophoresis and to the same position as E. coli OmpF when urea was incorporated into the gel. The mobility of this protein increased relative to that of OmpC in urea-containing gels as does E. coli OmpF. However, the same protein was also produced during axenic growth and during intraperiplasmic growth on prey lacking OmpF. The peptide profile generated by partial proteolysis of this protein showed no homology to that produced from E. coli OmpF. We conclude that B. bacteriovorus synthesizes an OmpF-like protein. Previous claims that the bdellovibrio incorporates an intact E. coli OmpF are not consistent with these observations.

Permeability of the boundary layers of Bdellovibrio bacteriovorus 109J and its bdelloplasts to small hydrophilic molecules.

Measurements of the sucrose-permeable and -impermeable volumes during Bdellovibrio bacteriovorus attack on Escherichia coli or Pseudomonas putida showed that the volume of the bdelloplast increased over that of the substrate cell. Although the pattern of the increase differed with the two organisms, the volumes reached maximum at about 60 min into the bdellovibrio growth cycle. By this time, the cytoplasmic membranes of the attacked cells were completely permeable to sucrose. The kinetics of increase in sucrosepermeable volumes were similar to the kinetics of attachment and penetration (Varon and Shilo, J. Bacteriol. 95:744-753, 1968). These data show that the original cytoplasmic and periplasmic compartmentalization of the substrate cell ceases to exist with respect to small hydrophilic molecules during bdellovibrio attack. In contrast, the effective pore size of the outer membrane of the substrate cell to small oligosaccharides remains unaltered during bdelloplast formation as was shown by direct measurements of its exclusion limits. The major porin protein of E. coli, OmpF, was recoverable from the bdelloplast outer membrane fraction until the onset of lysis. The Braun lipoprotein was removed from the bdelloplast wall early, and OmpA was lost in the terminal part of the bdellovibrio growth cycle.

Change in the surface hydrophobicity of substrate cells during bdelloplast formation by Bdellovibrio bacteriovorus 109J.

During intraperiplasmic growth of Bdellovibrio bacteriovorus 109J, the substrate cell surface becomes more hydrophobic. This was shown (i) by comparing the sensitivity to hydrophobic antibiotics of wild-type and lipopolysaccharide mutant strains of Salmonella typhimurium to that of the bdellovibrio growing on these strains and (ii) by measuring the binding efficiency of these strains, Escherichia coli, and their derived bdelloplasts to octyl Sepharose. The kinetics of increase in surface hydrophobicity was similar to the kinetics of the conversion of the substrate cell peptidoglycan to a lysozyme-resistant form (M. Thomashow and S. Rittenberg, J. Bacteriol. 135:1008-1014, 1978), and hydrophobicity reached a maximum at about 60 min in a synchronous culture. The change in hydrophobicity was inhibited by chloramphenicol, suggesting that bdellovibrio protein synthesis was required. Control experiments revealed that the free-swimming bdellovibrio had a more hydrophobic surface than the deep rough mutants of S. typhimurium.

The Microaerophile SPirillum volutans: Cultivation on Complex Liquid and Solid Media.

Spirillum volutans grows only under microaerobic conditions in a peptone-succinate-salts broth, but can grow aerobically when the peptone is replaced by vitamin-free acid-hydrolyzed casein broth. The addition of potassium metabisulfite, norepinephrine, catalase or superoxide dismutase (SOD) permitted aerobic growth in peptone-succinate-salts broth. A combination of catalase and SOD had a synergistic effect. S. volutans lacked catalase and had only a low level of peroxidase activity, but did possess SOD activity (12 to 14 U/mg of protein). The organism was found to be extraordinarily sensitive to exogenous hydrogen peroxide. Illumination of peptone-succinate-salts broth generated hydrogen peroxide and rendered the medium inhibitory to growth. A combination of catalase and SOD prevented this inhibition. Growth of S. volutans on solid media, not previously possible, was accomplished by the use of vitamin-free acid-hydrolyzed casein and peptone-succinate-salts agar media; maximum growth responses were dependent on the following combination of factors: addition of bisulfite, catalase, or SOD, protection of the media from illumination, incubation in a highly humid atmosphere, and incubation under atmospheres of 12% oxygen or less. The results indicate that the microaerophilic nature of S. volutans is attributable largely to the high sensitivity of the organism to exogenous hydrogen peroxide and, to a lesser extent, superoxide radicals occurring in the culture medium.

The microaerophilic nature of Treponema pallidum: enhanced survival and incorporation of tritiated adenine under microaerobic conditions in the presence or absence of reducing compounds.

Treponema pallidum, although sensitive to atmospheric concentrations of O2, requires low levels of O2 for optimal survival and metabolic activity. The addition of 0.0125-0.2 mg/ml of sodium metabisulfite to a basal medium consisting of Eagle's minimal essential medium and 50% fresh, heat-inactivated normal rabbit serum was found to have an effect similar to that of dithiothreitol in extending the survival of T. pallidum (Nichols strain) under 3% O2. Detailed analysis of the effect of O2 tension revealed that 50% motility was retained longest at atmospheric O2 concentrations of 1-5%, whether or not dithiothreitol or sodium metabisulfite were present. Concentrations of O2 of 3-10% were optimal for nucleic acid synthesis, as determined by [3H]adenine incorporation during the first 24 hr of incubation. Sodium metabisulfite was less effective than dithiothreitol in stimulating nucleic acid synthesis. Neither sodium metabisulfite nor dithiothreitol at their effective concentrations had any effect on levels of dissolved O2. During incubation under 3% O2, motility was maintained at > 50% for 15 days and virulence for at least 13 days by dilution of the treponemal suspensions every three days with fresh medium containing sodium metabisulfite. The optimal retention of motility and nucleic acid synthesis under microaerobic conditions in the absence of reducing compounds provides further evidence that T. pallidum is a microaerophilic organism.