Method for qualifying microbial removal performance of 0.1 micron rated filters. Part I: characterization of water isolates for potential use as standard challenge organisms to qualify 0.1 micron rated filters.

Although 0.1 microm rated filters intended for pharmaceutical sterilization applications have been commercially available for at least 15 years, there is no industry-wide standard for qualifying the microbial removal performance of these filters. In this article, we report on the bacterial challenge methodology used to screen four bacterial species for potential utility as a standard challenge organism to qualify 0.1 microm rated filters. These isolates were, in their natural state, demonstrated to penetrate 0.2/0.22 microm rated filters in prior studies. In the screening challenges described in this study, three out of these four candidates tested demonstrated consistent penetration of one 0.22 microm rated filter type tested (when cultured in a low nutrient medium under standard laboratory conditions). These included 6204-22 (FAME ID Acidovorax avenae citrulli), 6266-15 (FAME ID Comamonas acidovorans), and 6266-34 (FAME ID Hydrogenophaga pseudoflava). Of these, H. pseudoflava (6266-34) was chosen for additional experiments with other 0.2 microm rated filter membranes. In total, seventeen 0.2 and 0.22 microm rated filter discs, spanning five different "sterilizing grade" filter types from three different filter manufacturers were tested. H. pseudoflava penetration was observed for every filter tested. Under the same challenge conditions, H. pseudoflava was consistently retained by a 0.1 microm rated hydrophilic PVDF (polyvinylidenefluoride) filter with a specified high titer reduction claim for Acholeplasma laidlawii. In order to ensure selection of the most stable penetrative phenotype (i.e., select for nonrevertants), H. pseudoflava was subjected to three rounds of "filter cloning," and these results are described herein. The advantages of using H. pseudoflava for qualifying the microbial removal performance of 0.1 microm rated filters are also discussed.

Method for qualifying microbial removal performance of 0.1 micron rated filters. Part II: preliminary characterization of Hydrogenophaga (formerly Pseudomonas) pseudoflava for use as a standard challenge organism to qualify 0.1 micron rated filters.

In this article, we report on the preliminary characterization of Hydrogenophaga (formerly Pseudomonas) pseudoflava for potential use as a standard challenge organism to qualify 0.1 microm rated filters. Filter-cloned H. pseudoflava (ATCC 700892) was easily cultured in a low nutrient broth (R2A broth) under standard laboratory conditions, reaching high titers of 10(8)-10(9) cfu/mL within 48-65 hours of incubation at 25+/-5 degrees C. Under these conditions, H. pseudoflava is a rod-shaped bacterium, averaging 0.25+/-0.03 microm by 1.65+/-0.35 microm, and appears to be smaller than Brevundimonas diminuta in width (0.31+/-0.03 microm), but somewhat longer in length (0.88+/-0.19 microm), which may partly explain the observed penetration. In total, thirty-five 0.2/0.22 microm rated filter discs, spanning five different "sterilizing grade" filter types from two different filter manufacturers were challenged with H. pseudoflava. In all cases, H. pseudoflava was shown to consistently penetrate every 0.2/0.22 microm rated filter disc tested. These tests also spanned three different challenge durations, including short-term challenges (30-40 minutes), and two different challenge fluids. The use of serial (double) 0.22 mm rated filters, which is a common industry practice to reduce the prefiltration bioburden to the final "sterilizing" filter, was also shown to be inadequate to fully retain H. pseudoflava under the challenge condition used. In contrast, two different 0.1 microm rated filter types functionally qualified with a specified high titer reduction claim for Acholeplasma laidlawii, were shown to consistently and fully retain H. pseudoflava, and retention by these two filter types was shown to be robust and independent of the challenge duration.

Method for qualifying microbial removal performance of 0.1 micron rated filters. Part III: bacterial challenge tests on 0.2/0.22 and 0.1 micron rated filter cartridges with Hydrogenophaga (formerly Pseudomonas) pseudoflava.

We have previously reported on the preliminary characterization of Hydrogenophaga (formerly Pseudomonas) pseudoflava for potential use as a standard challenge organism to qualify 0.1 microm rated filters. This article reports on the retention efficiencies of a large panel of 0.2/0.22 microm and 0.1 microm rated filter cartridges for H. pseudoflava (ATCC 700892) versus the retention capabilities of the same filters for Brevundimonas diminuta (ATCC 19146). A total of thirty-two 0.2/0.22 microm rated filter cartridges, spanning nine different "sterilizing grade" filter types from four different filter manufacturers, were challenged with H. pseudoflava at challenge levels exceeding 10(7) cfu/cm2. H. pseudoflava was shown to penetrate every 0.2/0.22 microm rated filter tested, with log titer reduction (LTR) values ranging from 3.5 to 7.7 logs. H. pseudoflava was shown to be more penetrative than B. diminuta under the same challenge conditions. B. diminuta was fully retained by nineteen of the twenty 0.2/0.22 microm rated filters that were challenged with both organisms. In the case of 0.1 microm rated filters, eighteen filter cartridges, spanning five different filter types from three manufacturers were tested. H. pseudoflava was consistently retained by four out of the five filter types tested, with LTR values in excess of 11.5 to 12.2 logs. The 0.1 microm rated filter type that was penetrated by H. pseudoflava has been previously demonstrated to be not fully retentive for naturally occurring bacteria. The data show that H. pseudoflava penetrates 0.2/0.22 microm rated filters just as readily as B. diminuta penetrates 0.45 microm rated filters. In addition, titer reductions provided by 0.2/0.22 microm rated filters for H. pseudoflava are comparable to those reported for A. laidlawii mycoplasma, albeit under different conditions. This study demonstrates that H. pseudoflava meets all criteria for use as a standard organism for qualifying the microbial removal performance of 0.1 microm rated filters for enhanced sterility assurance.

Mollicutes-wall-less bacteria with internal cytoskeletons.

The structure and motility of the Mollicutes (Spiroplasma, Mycoplasma, and Acholeplasma) are briefly reviewed. The data are presented from the perspective of prokaryotic and eukaryotic motors, cytoskeletons, and cell motility. The Mollicutes are eubacteria derived from Clostridia by regressive evolution and genome reduction to produce the smallest and simplest free-living and self-replicating cells. Structurally, the Mollicutes are characterized by a complete lack of a cell wall and the presence of an internal cytoskeleton. Spiroplasma, which are helical cells with a flat, ribbon-like cytoskeleton, are amenable to structural and geometrical analysis. Motility and shape changes can be explained and modeled by the cytoskeleton acting as a linear motor.

Acholeplasma multilocale sp. nov., isolated from a horse and a rabbit.

Acholeplasma strains were isolated from the nasopharynx of a horse (strain PN525T [T = type strain]) and the feces of a rabbit (strain B1). One clone of strain PN525T and one clone of strain B1 were examined in detail. These clones were indistinguishable from each other and were serologically distinct from the previously described Acholeplasma and Mycoplasma spp. The strains had the following properties: guanine-plus-cytosine content of 31 mol%; sterol was not required for growth, which occurred under both aerobic and anaerobic conditions; glucose was metabolized; and arginine was hydrolyzed. Strain PN525 (= NCTC 11723) is the type strain of a new species, Acholeplasma multilocale.

Acholeplasma cavigenitalium sp. nov., isolated from the vagina of guinea pigs.

A mollicutes isolated from a guinea pig vagina was shown to be serologically distinct from previously recognized Mycoplasma and Acholeplasma species. Colonies isolated from 10 different guinea pigs were cloned and examined in detail. These strains were closely related and had the following properties: guanine-plus-cytosine content of 36 mol%, no requirement for sterol, and aerobic growth. Glucose was not metabolized, and arginine and urea were not hydrolyzed. Strain GP3 (= NCTC 11727) is the type strain of a new species, Acholeplasma cavigenitalium.

Mycoplasma viruses.

Unlike bacterial viruses that infect cells bounded by a cell wall, mycoplasma viruses have evolved to enter and propagate in mycoplasma cells bounded only by a single lipid-protein cell membrane. In addition, mycoplasmas have the smallest amount of genetic information of any known cells, so their complexity is constrained by a limited genetic coding capacity. As a consequence of these host cell differences, mycoplasma viruses have been found to have a variety of structures and replication strategies which are different from those of the bacterial viruses. This article is a critical review of mycoplasma viruses infecting the genera Acholeplasma, Spiroplasma, and Mycoplasma; included are data on classification, morphology and structure, biological and physical properties, chemical composition, and productive and lysogenic replication cycles.

Insect cell cultures in the study of attachment and pathogenicity of spiroplasmas and mycoplasmas.

The insect cell lines Dm-1 (Drosophila melanogaster), AS-2 (Aceratagallia sanguinolenta) and AC-20 (Agallia constricta) were infected with spiroplasmas, mycoplasmas and Acholeplasma laidlawii. In Dm-1 cultures maintained at 25 degrees C in M1A medium, all strains multiplied except M. hyorhinis and the uncultivable sex-ratio organism. Spiroplasma citri R8A2, S. floricola BNR-1 and OBMG, S. apis PPS-1 and the strains BC-3, corn stunt spiroplasma (CSS) and 277F produced cytopathogenic effects (CPE), whereas S. mirum SMCA, M. orale, M. arginini and A. laidlawii did not. Cytadsorption was found with the cultivable spiroplasmas and A. laidlawii. At 30 degrees C SMCA, M. orale, M. arginini and A. laidlawii killed the Dm-1 cultures. M. hyorhinis grew without any CPE. In AS-2 and AC-20 cultures grown at 28 degrees C in LB medium, R8A2, B88, 277F, BNR-1 and PPS-1 multiplied and reached titres of 2 X 10(8) to 4 X 10(9) CFU/ml. They produced CPE leading to culture death. CSS did not grow. R8A2 reached higher titres in AS-2 cultures than in fresh LB medium. This stimulating factor was studied by means of conditioned medium. All 6 spiroplasmas cytadsorbed to AS-2 and AC-20 cells. B88 and 277F adsorbed heavily, while the other 4 strains adsorbed only slightly. Fluorescent DNA staining with "Hoechst 33258" revealed the presence of non-helical forms inside the cells.

The Emmy Klieneberger-Nobel Award lecture. Reflections on recovery of some fastidious mollicutes with implications of the changing host patterns of these organisms.

Major advances have occurred the past few years in the cultivation of a number of new, fastidious mollicutes--events which can be traced directly to successful efforts to develop culture media for the expanding group of helical mollicutes (spiroplasmas) inhabiting plants and arthropods. A description of cultivation techniques successful in primary isolation of three unusual mollicutes, representing new mycoplasmas from man and animals and a new spiroplasma from ticks, emphasizes some important factors in recovery of wall-less prokaryotes with special cultural requirements. Vigorous efforts to understand the distribution of spiroplasmas in plant and insect hosts also led to the cultivation of new, non-helical mollicutes. Preliminary characterization of a number of these new agents offers strong evidence for a unique and distinct Acholeplasma and Mycoplasma flora of both plants and insects.

Isolation and characterization of Mycoplasma and Acholeplasma from apparently healthy and diseased (infectious sinusitis) turkeys.

Investigation of 136 turkeys (24 manifesting infra-orbital sinusitis, 112 apparently healthy) resulted in isolation of 79 strains of Mycoplasma and 4 of Acholeplasma. By the disc growth inhibition test with 16 reference antisera of avian serogroups, 55 strains were identified serologically and 28 remained unidentified. Thirteen strains of Mycoplasma gallisepticum, 1 of M. meleagridis, and 2 of Acholeplasma laidlawii were isolated from turkey sinusitis whereas serogroups C (2), D (19), F (8), M. meleagridis (4), M. anatis (4), A. laidlawii (2), and 28 unidentified strains were isolated from apparently healthy turkeys. Three patterns were recognized on the basis of glucose, maltose, and sucrose, fermentation. The most frequent, pattern I, included 13 M. gallisepticum strains whereas 5 M. meleagridis strains belonged to fermentation pattern III. Isolates were also studied for reduction of tetrazolium, methylene blue, potassium tellurite, resistance to methylene blue and sodium taurocholate, and production of arginine deiminase and "film and sports." Inoculation of selected isolates into developing chick embryos revealed that 2 A. laidlawii strains were nonpathogenic and 13 M. gallisepticum, 1 serogroup D and 2 serogroup F strains were pathogenic, causing 50--100% mortality. In vitro antibiotic disc sensitivity tests indicated that rovamycin (solubilized spiramycin) may be recommended for turkey mycoplasmosis. Isolation of 2 A. laidlawii strains from turkey sinusitis and 4 M. anatis strains from apparently healthy turkeys appears interesting.