An L-Form of Staphylococcus aureus Adapted to a Brain Heart Infusion Medium without Osmotic Stabilizers

An L-form derived from halotolerant Staphylococcus aureus Tasaki was adapted to growth in a brain heart infusion medium without any supplemental osmotically protective solutes (360 mOsm/kg). This L-form had no chemically detectable peptidoglycan residues on its surface. Electron microscopic observations confirmed morphologically the absence of the structures and also of other osmotically protective polymers within or exterior to the cytoplasmic membrane. The osmotic stability and susceptibility to bacitracin, d-cycloserine, and vancomycin of the L-form adapted to growth in 360 mOsm osmotically unprotective medium was higher than that of the L-form grown in 1,950 mOsm supplemented with 4.5% NaCl. The adapted L-form tended to be more sensitive to almost all of the antibiotics examined, other than the inhibitors for cell wall-synthesis, than the original L-form strain requiring osmotic protection for growth. Chemical analysis of the membrane of the adapted L-form indicated 16.3% total lipids and 20.6% proteins by dry weight of the membrane, and it contained larger amounts of lipid phosphorus (20.0 μ/mg).     

Membrane studies of Streptococcus pyogenes and its L-form growing in hypertonic and physiologically isotonic media. An electron spin resonance spectroscopy approach.

Electron spin resonance spectroscopy (ESR) was used to compare the lipid organization, thermal stability and the physical state of the membrane of a human pathogen, Streptococcus pyogenes and its osmotically fragile L-form with this same L-form now adapted to grow under physiologically isotonic conditions (physiological L-form). Comparison of the hyperfine splittings of a derivative of 5-ketostearic acid spin label, I(12, 3), after incorporation into the membrane, revealed that the lipid chain rigidity of these membranes is in the order physiological L-form greater than osmotically fragile L-form greater than streptococcus. The signal intensity (of the center magnetic field line) versus temperature analysis showed two transitions for these membranes. The first with melting points of 45, 26 and 36 degrees C and second transition at 70, 63 and 60 degrees C for the physiological L-form, osmotically fragile L-form and streptococcal membranes, respectively. This same order of membrane lipid chain rigidity was seen from the cooperativities obtained for each of these systems from analysis based on the expression for an n-order reaction. The I(12, 3) and other probes with the paramagnetic group close to the methyl end of the molecule suggested that this difference in lipid chain rigidity between these organisms resides in the environment closer to the lipid head group region rather than in the hydrophobic lipid core. Another major finding was the binding of I(12, 3) at two or more different sites in each of the membranes examined. This change in lipid chain rigidity now provides an explanation to account for the survival of a previously osmotically fragile L-form in physiologically isotonic media by focusing on changes in the physical nature of its membrane. In so doing, it adds to and reinforces the speculation of the potential survival in vivo and involvement in pathogenesis of osmotically fragile aberrant forms of bacteria.     

Membrane Studies of Streptococcus pyogenes and its L-form growing in hypertonic and physiologically isotonic media. An electron spin resonance spectroscopy approach

Electron spin resonance spectroscopy (ESR) was used to compare the lipid organization, thermal stability and the physical state of the membrane of a human pathogen, Streptococcus pyogenes and its osmotically fragile L-form with this same L-form now adapted to grow under physiologically isotonic conditions (physiological L-form). Comparison of the hyperfine splittings of a derivative of 5-ketostearic acid spin label, I(1 2, 3), after incorporation into the membrane, revealed that the lipid chain rigidity of these membranes is in the order physiological L-form > osmotically fragile L-form > streptococcus. The signal intensity (of the center magnetic field line) versus temperature analysis showed two transitions for these membranes. The first with melting points of 45, 26 and 36 °C and second transition at 70, 63 and 60 °C for the physiological L-form, osmotically fragile L-form and streptococcal membranes, respectively. This same order of membrane lipid chain rigidity was seen from the cooperativities obtained for each of these systems from analysis based on the expression for an $\text{n-}\text{order}$ reaction. The I(12,3) and other probes with the paramagnetic group close to the methyl end of the molecule suggested that this difference in lipid chain rigidity between these organisms resides in the environment closer to the lipid head group region rather than in the hydrophobic lipid core. Another major finding was the binding of I(12, 3) at two or more different sites in each of the membranes examined. This change in lipid chain rigidity now provides an explanation to account for the survival of a previously osmotically fragile L-form in physiologically isotonic media by focusing on changes in the physical nature of its membrane. In so doing, it adds to and reinforces the speculation of the potential survival in vivo and involvement in pathogenesis of osmotically fragile aberrant forms of bacteria.     

Serum inhibits penicillin-induced L-form growth in Staphylococcus aureus: a note of caution on the use of serum in cultivation of bacterial L-forms.

Heat-inactivated horse serum inhibited penicillin-induced L-form colony formation in Staphylococcus aureus when included in an osmotically stabilized culture medium. Most, perhaps all, L-form colonies that appeared with low frequencies on the serum-supplemented medium were of the penicillin-independent, stable type. This relationship must be taken into account when use of serum is considered for L-form cultivation.     

Morphology, growth and reversion in a stable L-form of Escherichia coli K12

An L-form isolated from Escherichia coli K12 by sequential treatment with N-methyl-N'-nitro-N-nitrosoguanidine and lysozyme was adapted to grow in hyperosmolar liquid cultures. It was stable in the absence of antibiotic when cultured in brain heart infusion (BHI) broth containing NaCl and CaCl2, the optimal concentrations being 0.34 M and 1 mM, respectively. No growth of the L-form was observed when CaCl2 was not added to BHI medium containing 0.34 M-NaCl. On the other hand, when KCl replaced NaCl as the osmotic stabilizer, growth of the L-form was repressed in the presence of CaCl2. Electron microscopy of the L-form confirmed the absence of a cell wall. A revertant strain derived from the L-form grew as a stable bacillary form in BHI medium without osmotic stabilizer. The growth characteristics of the revertant strain resembled those of the parent strain. The revertant strain produced L-forms in the presence of NaCl.     

Development of callus and suspension cultures of potato resistant to NaCl and mannitol and their response to stress

Callus and suspension cultures adapted to various concentrations of NaCl or mannitol were developed from the cultivated potato Solanum tuberosum cv. Desire. Growth of the calli was less inhibited by mannitol than by iso-osmotic concentrations of NaCl. Reduction of growth by both NaCl and mannitol was considerably lower in osmotically adapted calli than in non-adapted ones. Salt-adapted suspension cultures that grew in the medium to which they had been originally adapted had a shorter lag in growth as well as a shorter time required to achieve the maximum growth, as compared with non-adapted cells. Suspension cultures adapted to NaCl concentrations higher than 150 mM were obtained only after preadaptation to osmotic stress. Adaptation of these cells was found to be stable. Accumulation of Na⁺ was lower and level of K⁺ was more stable in osmotically adapted than in non-adapted calli, when both were exposed to salt. Potassium level in NaCl-adapted calli exposed to saline medium was lower than that in non-adapted calli in standard medium. The maximum of Cl^– and Na⁺ accumulation was reached at higher external salt concentration in salt-adapted than in non-adapted suspension cultures. In both callus and suspension cultures, Cl^– accumulated more than Na⁺. Potassium level decreased more in non-adapted than in NaCl-adapted suspension cultures. The decrease of osmotic potential in osmotically adapted calli exposed to mannitol and in salt-adapted calli and suspension cultures exposed to salt was correlated to the increase of the external concentration. Such a correlation was not found in osmotically adapted calli exposed to salt. Non-electrolytes were found to be the main contributors to the decrease is osmotic potential in both callus and suspension cultures.     

Induction of Enterococcal L-Forms by the Action of Lysozyme

Suspensions of enterococci were treated with lysozyme in the presence of osmotic stabilizers. The resulting osmotically fragile bodies prepared from Streptococcus faecium strain F24 and S. faecalis strain E1 gave rise to L-forms under optimal osmotic and nutritional conditions for treatment and subsequent growth. The most critical component of the growth medium, to obtain maximum yields, was the nature and concentration of the added salt. The two most effective salts were sodium chloride and ammonium chloride in the range of 2 to 3% (w/v) added to a suitable agar base. Ammonium chloride was more versatile, because it could be used with either sucrose or polyethylene glycol 4000 as the osmotic stabilizer for preparation and dilution of the osmotically fragile bodies. Sodium chloride would not consistently support growth of S. faecium F24 as L-forms when polyethylene glycol 4000 was used as the osmotic stabilizer during lysozyme treatment. Time-course studies of concurrent cell wall removal and L-form induction suggested that maximal induction required only cell wall damage rather than complete wall removal. This method for induction of L-forms from a suspension of enterococci is a significant improvement over other presently known methods.     

Membrane lipoteichoic acid of Streptococcus pyogenes and its stabilized L-form and the effect of two antibiotics upon its cellular content.

Membrane lipoteichoic acid continues to be synthesized by an osmotically fragile, stabilized L-form of Streptococcus pyogenes. Chromatographic and electrophoretic comparisons indicate that the lipid componenent of lipoteichoic acid in this L-form and its parental streptococcus is glycerophosphoryldiglucosyl diglyceride and not phosphatidylkojibiosyl diglyceride. Based upon dry weight determinations, the yield of lipoteichoic acid from the L-form is 0.19%, as compared with 0.97% from the streptococcus. When grown with bacitracin the L-form contains the same amount of teichoic acid as when grown without this antibiotic; however, its lipoteichoic acid content is reduced by 85%. Similarly, the L-form grown with novobiocin for 10 h contains only 17% of the teichoic acid found in control cells.     

Defined Physiological Conditions for the Induction of the L-Form of Neisseria gonorrhoeae

Defined conditions are described which allowed luxuriant growth over continuous subculture of strains of Neisseria gonorrhoeae in broth and on agar. Growth was equal to or surpassed that observed in Mueller-Hinton broth or on Mueller-Hinton blood agar. The final medium adopted consisted of medium 199 and a supplemental mixture of cysteine, glucose, and various salts. Addition of sodium bicarbonate or CO(2) enrichment was not required. For solidification, only agarose allowed growth of all strains; glutamic acid stimulated growth of two strains but was inhibitory for a third. The addition of 8% polyvinylpyrrolidone (PVP), 2% purified albumin, and penicillin resulted in induction of all three strains to the L-form with frequencies up to 0.3%. At present no induction to the L-form has been achieved in the absence of albumin. Various lots of PVP proved toxic in the defined medium, and extensive dialysis was required for good growth and L-form induction. Substitution of PVP with sucrose indicated a sucrose toxicity for the parental gonococcus even on the addition of albumin. L-form induction did occur on sucrose L-medium but at significantly lower frequencies. The colonies appeared 1 week later than those on PVP L-medium but at significantly lower frequencies. The colonies appeared 1 week later than those on PVP L-medium and remained very small and poorly developed.     

Induction and cultivation of a stable L-form of Bacillus subtilis

The induction of L-forms of Bacillus subtilis from protoplasts is described. The method involved the frequent subculture of the unstable L-form on a growth medium supplemented with lysozyme and horse serum. A stable culture, which did not revert when lysozyme and horse serum were omitted from the medium, was obtained after 13 subcultures. This culture could be grown on solid and in liquid medium by routine microbiological methods. Long-term storage of these cells was achieved by freeze drying and maintenance in glycerol at −70°C. The cultural adaptability of the L-form is described and discussed with respect to methods of cultivation and growth.     

Characterization of a Stable L-Form of Bacillus subtilis 168

A stable L-form of Bacillus subtilis 168 (sal-1) has been isolated which grows and divides logarithmically in liquid medium with a generation time of 60 min. This mutant does not synthesize cell wall as evidenced by chemical, biochemical, and morphological analyses. Antibiotics which specifically inhibit cell wall biosynthesis do not affect the growth of the L-form. Significant differences exist between the membrane proteins of the bacillary form and the L-form. The relative profile of membrane proteins varies with the salt concentration of the medium in both the L-form and the bacillary form.     

Intracellular responses of productive hybridomas subjected to high osmotic pressure

It has previously been found tht hybridoma cells undr hyuerosmotic stress produce higher amounts of antibody. This study indentified the cellular processes and mechanisms that occur during this event. In studies fo hybridomas adpated toosmolarities ranging between 300 and 450 mOsm (uusing NaCl), antibody production increased to a saturation level while cell growth decreased progressively. At 500 mOsm, lower, cell numbers and markedly decreaased productivity resulted. Sucrose and KCl were found to induce similar trends, except to different extents.Several important change in cellulaes in cellular responses were onsserved. Elevation of osmnolarity with NaCl from 300 to 350 mOsm causes an increase of zwiterionic amino acid upatake, which, occurredvia Na(+)-dependent transport systems. In particuar, systedm A was enhanced by 1.86-fold, but noenhancement was observed for Na(+)-independent transport systems, In addition, amino acids reactive with Na(+)-dependent transport systems were onserved to be abundant within osmotically stressed hybridomas in the middle and dlate exponentoial statges. Sucroses ans Kcl caused similar uptake effects, but to a laeeser degree, as long as sodium ions were present in solution.Specific consumption rates fo glucose and glutamine incresase by 19% and 20%, respectively, under high osmolarity treatment. Thewse increases were confirmed by the 5% to 10% increase in cellular metabolic acitivity. At 350 mOsm, growth rate was slower, compared with the 300-mOsm culture, which was reflected by thelower DNA conetr4ation. Stressed cultures contained enhanced leyls of tatal RNA content could in turn increase the translation rates of proteins. This was reflected in the accumulation of both dry cell weight and total cellular protein at linear rates of 0.42 muG/10(6) cells/mOsm and 0.21 mug/10(6) cells/mOmsm, respectively, with increasing osmolarty between 300 and 450 mOsm.Overall, hybridoms increased their metabolic activities and amino acids uptake via the Na(+)-dependent symports to compensate for teh osmotically elevated external environment. These effects contribute directly and indirectly tothe increased cell mass consisting of a larger pool of amono acids, RNA, cellular proteins, and seecreted antibody produt. (c) 1995 John Wiley & Sons, Inc.     

Induction and cultivation of a stable L-form of Bacillus subtilis

The induction of L-forms of Bacillus subtilis from protoplasts is described. The method involved the frequent subculture of the unstable L-form on a growth medium supplemented with lysozyme and horse serum. A stable culture, which did not revert when lysozyme and horse serum were omitted from the medium, was obtained after 13 subcultures. This culture could be grown on solid and in liquid medium by routine microbiological methods. Long-term storage of these cells was achieved by freeze drying and maintenance in glycerol at -70 degrees C. The cultural adaptability of the L-form is described and discussed with respect to methods of cultivation and growth.     

Use of a Tetrazolium-based Cell Proliferation Assay to Measure Effects of In Vitro Conditions on Perkinsus marinus (Apicomplexa) Proliferation

ABSTRACT. Because the in vitro cell cycle of the apicomplexan oyster pathogen Perkinsus marinus generates cell populations heterogeneous for size and typified by aggregation, both turbidimetric and counting methods for determining population densities and proliferation rates are inaccurate or cumbersome. We show that a commercial, tetrazolium-based cell proliferation assay yields a soluble formazan chromophore upon intracellular reduction by P. marinus . at a rate proportional to cell population biovolume. Using this assay system, we have 1) defined selected culture system parameters which maximize P. marinus in vitro proliferation, 2) assessed selected chemosensitivities, and 3) standardized the assay system for quantification of densities and doubling times of populations propagated with our optimized system. Growth was supported by four tested base media and was maximized in 1:1 DME/Ham's F-12. Temperatures of 10–40° C permitted growth, which was maximized at 35° C. pH 6.0–8.5 permitted growth, which was maximized at 7.0–7.5. Osmolalities of 340–1,930 mOsm supported growth, which was maximized at 790 mOsm. Serum supplements from 1–10% (v/v) did not enhance log phase growth, but enhanced stationary phase metabolic activity in proportion to concentration. Our isolate (ATCC 50439) has a 13 h log phase doubling time when propagated under optimized conditions: 28° C, 800 mOsm, pH 7.0, 1:1 DME/Ham's F-12 medium, 5% (v/v) FBS. It is tolerant of antibacterial agents at concentrations commonly used in vertebrate tissue culture, but is inhibited by several antimycotics at similar concentrations.     

Rat renal papillary tissue explants survive and produce epithelial monolayers in culture media made hyperosmotic with sodium chloride and urea

The capacity of papillary cells to adapt to elevated osmotic concentrations is unusual among mammalian cells. This capacity was evaluated by using primary tissue culture. Viability and growth of cells in rat renal papillary tissue explants were assessed after culture in media adjusted with urea and sodium chloride to various osmotic concentrations between 300 and 1,500 mOsm/kg water. The survival of cells, including cells resembling those of the collecting ducts and the loop of Henle, was greatest in medium adjusted to 1,000 mOsm with equiosmolar amounts of the two solutes. At 1,500 mOsm only cuboidal tubular epithelium resembling collecting duct epithelial cells survived. In contrast, cells of cortical tissue survived and grew at 300 and 640 mOsm, but not at 1,000 mOsm or above. Epithelial monolayers appeared to proliferate from collecting ducts and spread over the surface of the explants as well as onto the glass surface in the culture dish. Epithelial growth of medullary tissue was most rapid at 300 mOsm and was slower at 700 and 1,000 mOsm. Monolayers did not form at 1,500 mOsm; however, epithelial overgrowth of explants did occur. Hydropenia in the donor animal did not significantly affect the viability or growth of cultured papillary tissue. Explants cultured for 5 days at 300 mOsm followed by a stepwise increase in medium osmolality to 1,100 or 1,500 mOsm and cultured for 3 more days showed low or no survival whereas explants cultured at 700 mOsm survived such increases. Explants cultured for 5 days at 1,500 mOsm survived and grew monolayers when lowered to 300 mOsm. Poor viability and no epithelial proliferation were observed in explants cultured in medium adjusted to 900 mOsm with either urea or sodium chloride alone, suggesting that a mixture of the two solutes in the extracellular space, as found in vivo, may be essential in achieving elevated osmolalities.     

Use of transformation for studying the nature of formation of stable bacterial L forms]

The authors obtained a stable variant of the L-forms of Bacillus subtilis capable of exponential growth of the minimal and synthetic medium. An electron-microscopic study of different stages of the L-form formation was carried out by the method of ultra-thin sections. A possibility was shown of the transfer of the L-form formation sign by the method of transformation. DNA isolation from the L-forms by soft lysis considerably facilitated and simplified the genetic analysis of the L-form formation by the transformation method.     

细菌L型的厌氧诱导和培养

厌氧条件下以羧卡青霉素诱导金黄色葡萄球菌、大肠杆菌和蜡样芽胞杆菌形成Ｌ型,观察细菌Ｌ型在厌氧条件下的形成、形态、生长及时渗透压的敏感性等特性。结果表明：蜡样芽胞杆菌在厌氧条件下不能形成Ｌ型或其Ｌ型在厌氧条件下亦不能返祖。金黄色葡萄球菌和大肠杆菌在厌氧条件下虽能诱生Ｌ型,但形成丝状体的构成Ｌ型菌落难以传代培养,厌氧培养未见Ｌ型圆球体和典型Ｌ型油煎蛋样菌落。金黄色葡萄球菌Ｌ型在含１％～１０％ＮａＣｌ的Ｌ型培养基上可生长形成Ｌ型菌落或非菌落形式存在的Ｌ型巨形体;大肠杆菌和蜡样芽胞杆菌的Ｌ型在含２％～６％ＮａＣｌ的Ｌ型培养基上可生长形成Ｌ型菌落或非菌落形式存在的Ｌ型巨形体。涂片染色或返祖试验证实细菌Ｌ型在含０．５％ＮａＣｌ的Ｌ型培养基或常规细菌学培养基上亦可生存。非菌落性Ｌ型巨形体和丝形体是细菌Ｌ型在琼脂培养基上广泛的存在形式。     

Efficiency of procedures for induction and cultivation of Pseudomonas syringae pv. pisi L-form

The L-form of Pseudomonas syringae pv. phaseolicola has been proved to induce resistance to bean halo blight.Various procedures were tested to induce the L-form of Pseudomonas syringae pv. pisi for its potential use as biocontrol agent of pea bacterial blight. Cell-wall deficient cells were induced in a liquid medium with penicillin following a protocol described for P. s. pv. phaseolicola. Cell growth on solid induction medium developed as typical granular and vacuolated structures, and characteristic colonies were observed in the first transfer. However, there was poor growth in subsequent transfers and some reversion to the parental type. To improve the induction procedure, the following new procedures were applied: (1) viability of cells was monitored during induction. The optimum induction time in liquid medium with penicillin was lower for pv. pisi than for pv. phaseolicola. Viability of L-forms in solid induction medium with penicillin was low and decreased in time. (2) the inducer ticarcillin was combined with clavulanic acid, which prevented the reversion to the parental type and (3) a range of concentrations of penicillin and ticarcillin/clavulanic acid was applied by the spiral gradient endpoint method for calculation of minimum inhibitory concentrations (MIC). Based on the results from these tests an induction method for P. s. pv. pisi L-form is proposed and the relevance of L-form is discussed for practice.     

Effect of Ca2+ and K+ on the intracellular pH of an Escherichia coli L-form.

The L-form NC7, derived from Escherichia coli K12, grew in a complex medium containing 0.2 M-CaCl2 as osmotic stabilizer, but not at pH values above 7.8. The cessation of growth at alkaline pH was not due to cell death. In complex media containing K+ or Na+, the L-form grew ove a wide pH range. Growth at alkaline pH was inhibited by 1 mM-amiloride, indicating that Na+/H+ antiport activity was required for growth at alkaline pH. The internal pH (pHi) of the L-form in media containing K+, Na+ or Ca2+ was constant at about 7.8 to 8.0 at external pH (pHo) values of 7.2 and 8.2. The rates of O2 consumption by intact cells, lactate oxidation by membrane vesicles from cells grown in Ca(2+)-containing medium, and cell division were all strongly repressed under alkaline conditions.     

Osmotic adjustment in the filamentous fungus Aspergillus nidulans.

Aspergillus nidulans was shown to be xerotolerant, with optimal radial growth on basal medium amended with 0.5 M NaCl (osmotic potential [psi s] of medium, -3 MPa), 50% optimal growth on medium amended with 1.6 M NaCl (psi s of medium, -8.7 MPa), and little growth on medium amended with 3.4 M NaCl (psi s of medium, -21 MPa). The intracellular content of soluble carbohydrates and of selected cations was measured after growth on basal medium, on this medium osmotically amended with NaCl, KCl, glucose, or glycerol, and also after hyperosmotic and hypoosmotic transfer. The results implicate glycerol and erythritol as the major osmoregulatory solutes. They both accumulated during growth on osmotically amended media, as well as after hyperosmotic transfer, except on glycerol-amended media, in which erythritol did not accumulate. Furthermore, they both decreased in amount after hypoosmotic transfer. With the exception of glycerol, the extracellular osmotic solute did not accumulate intracellularly when mycelium was grown in osmotically amended media, but it accumulated after hyperosmotic transfer. It was concluded that the extracellular solute usually plays only a transient role in osmotic adaptation. The intracellular content of soluble carbohydrates and cations measured could reasonably account for the intracellular osmotic potential of mycelium growing on osmotically amended media.