Variables Influencing Results, and the Precise Definition of Steps in Gram Staining as a Means of Standardizing the Results Obtained

Results of a Gram staining procedure varied with modifications of each of the steps involved. The best Gram differentiation was obtained when crystal violet and iodine solutions of high concentrations were used, and when n-propyl alcohol was used as the decolorizer. The decolorization step must be carefully quantitated, and one of the most important variables observed was whether a slide was brought into the decolorizer wet, or dry. Dry slides took 6 to 12 times as long to decolorize as wet. Wash steps, following crystal violet, and following the decolorizer, also greatly influence results by causing Gram-positive organisms to appear to be Gram-negative. The results indicated that Gram-stain procedures should not be varied to suit the whims of individual operators, and that each step could be specifically defined both as to the reagent used, and the procedure to be followed.

The followng Gram procedure is recommended for heat-fixed bacterial smears on glass slides. Flood the slide with Hucker's crystal violet for 1 ruin. Wash for 5 sec by dipping into tap water running into a 250 ml beaker at a rate of 30 ml per sec Rinse off the excess water with Burke's iodine, flood the slide with this solution for 1 min, then wash 5 sec in tap water as above. Decolorize by passing the wet slide through 3 (75 × 25 mm) Coplin dishes containing n-propyl alcohol, decolorize 1 min in each dish for a total of 3 min. Wash 5 sec in tap water as above, rinse off the excess water with 0.25% safranin, then flood the slide with this solution for 1 min. Wash as above, blot dry, and examine. An alternate procedure for decolorization would be to use either 95% n-propyl alcohol or 95% ethyl alcohol, but shorten the decolorization time to 30 sec per dish for a total of 1.5 min. After 10 slides, the decolorizer in the first dish should be replaced by fresh. This dish is then placed last in the sequence, with dish No. 2 moved to the No. 1 position.     

Ultra-Thin Sectioning for Electron Microscopy

A technic is described for obtaining thin sections of animal tissue suitable for electron microscopy. Fixation is accomplished by perfusion of the whole animal with neutral formalin or alcohol formalin followed by immersion of pieces to be examined in neutralized osmium tetroxide. The embedding medium is a mixture of equal parts of n-butyl and ethyl methacrylate polymerized by ultra-violet light. Sectioning is done by means of a glass knife on an International ultra-thin sectioning microtome set at 0.1 μ. The sections are floated on warm water to spread, then placed on Formvar-coated grids, dried, and put into toluene to dissolve the plastic. The technic produces routinely usable, thin sections that show a minimum of damage owing to fixation, embedding, and sectioning.     

Serial Sections of Smears for Electron Microscopy

Ultrathin sections for electron microscopy may be prepared from smears or squashes embedded in methacrylate. The cover slip or glass slide with the attached fixed cellular material is passed through alcohols to methacrylate monomer and finally to monomer containing a catalyst. The portion of the smear to be sectioned is covered with a gelatin capsule containing partially polymerized methacrylate. When polymerization is completed at 47°C, the hardened block is separated from the cover slip and trimmed under the compound microscope so as to encompass the desired area. Photographs are made of the intact smear to afford a basis for identification of cellular materials in electron micrographs of the individual ultrathin sections.     

Enzyme immobilization by radiation-induced polymerization of 2-hydroxyethyl methacrylate at low temperatures.

Enzyme immobilization by radiation-induced polymerization of hydrophilic glass-forming monomers, such as 2-hydroxyethyl methacrylate, was studied. Enzyme radiation damage could be sufficiently retarded at low temperatures. The immobilized enzyme activity yield was markedly higher at low temperature than at higher temperature polymerization. At low temperatures the polymerized composite had a porous structure owing to ice crystallization which depends on the monomer concentration. It was deduced that the enzyme was partially trapped on the polymer surface, partially isolated in the pore, and partially occluded inside the polymer matrix. A decrease in activity caused by enzyme leakage was observed with repeated use in enzyme reactions where the composites had a large porosity. The activity yield showed a maximum at certain optimum porosities, i.e., at optimum monomer concentrations. Continuous enzyme reaction was preferably carried out using immobilized enzyme columns.     

A Plastic Embedding Medium for Thin Sectioning in Light Microscopy

Tissue blocks with surface areas up to 2 cm² can be sectioned at 1 or 2 μ after embedding in a medium consisting of: methyl methacrylate, 27 ml; polyethylene glycol distearate MW 1540, 6 gm; dibutyl phthalate, 4 ml; and Plexiglas molding powder A-100, 9 gm (added last). The methacrylate mixture is polymerized at 50° C by benzoyl peroxide, 0.8 gm/ 100 ml of methacrylate. The polymerized matrix is transparent and the blocks can be cut on a rotary microtome with a steel knife. The plastic can be removed from sections with acetone prior to staining. Artifacts caused by embedding and sectioning are negligible     

Podophyllotoxin resistance: A codominant selection system for quantitative mutagenesis studies in mammalian cells

Mutants resistant to the microtubule inhibitor podophyllotoxin (Pod^R), a codominant marker, can be readily selected in various mammalian cell lines such as, CHO, HeLa, mouse L cells, Syrian hamster cells (BHK₂₁) and a mouse teratocarcinoma cell line OC15. In CHO cells, the recovery of Pod^R mutants is not affected by cell density (up to 1 × 10⁶ cells per 100-mm diameter dish), and after treatment with the mutagen ethyl methanesulfonate maximum mutagenic effect is achieved after a relatively short expression time (40–48 h). The frequency of Pod^R mutants in various cell lines increased in a dose-dependent manner in response to treatment with the mutagens ethyl methanesulfonate and N-methyl-N′-nitro-N-nitrosoguanidine. The Pod^R selection system thus provides a new genetic marker which should prove useful in studies of quantitative mutagenesis in mammalian cells.     

Methacrylate Embedding and Sectioning of Calcified Bone

Twenty-five milliliter aliquots of ethyl-butyl (1:1) methacrylate were polymerized at 6 or 7 initiator concentrations using 3 polymerization temperatures, both in air and in a water bath. Duplicate series were polymerized with and without vibration, pre-polymerization, and exclusion of oxygen. Hardening times and maximum temperatures reached within the samples were recorded. Vibration and the exclusion of oxygen had no effect. Prepolymerization, increasing polymerization temperature and increasing initiator concentration all decreased the hardening time and increased the maximum temperature. Polymerizing in a water bath rather than in air reduced the maximum temperature by 25-40°C and lengthened the hardening time about 1 hr. An initiator concentration of 0.4% Luperco CDB in ethyl-butyl methacrylate and a water-bath temperature of 45°C were selected for tissue embedding. The hardening time was 8 hr and the maximum temperature during polymerization was about 60°C.

Split rat femora and tibiae were freeze-dried and vacuum-infiltrated with acetone, absolute alcohol or monomer. The acetone or alcohol-fixed specimens were subsequently infiltrated with monomer. The specimens were transferred to 1 oz bottles, prepolymerized syrup added, and polymerized. No consistent differences between specimens treated by these methods were noted. Five-micron serial sections could be cut using a Leitz sledge microtome with a modified knife if the block was coated with paraffin between sections.     

Cerium as amplifying agent--an improved cerium-perhydroxide-DAB-nickel (Ce/Ce-H2O2-DAB-Ni) method for the visualization of cerium phosphate in resin sections

A new visualization (Ce/Ce-H2O2-DAB-Ni) procedure for cerium (Ce III) phosphate in semithin and ultrathin plastic sections (Epon 812, Lowicryl K4M, glycol methacrylate) of rat kidney tissues that had been incubated before embedding for the demonstration of phosphatases (alkaline and acid phosphatase, 5(1)-nucleotidase, Mg-dependent ATPase) is described. For this purpose the hydrophobic Epon resin was removed in NaOH-ethanol solution, whereas the hydrophilic Lowicryl and methacrylate sections did not required any etching. The primary reaction product Ce III-phosphate was amplified in a Ce III-citrate solution, subsequently oxidized with H2O2 and then visualized in a H2O2 containing DAB-nickel medium (Ce IV-perhydroxy induced DAB polymerization principle). The method yielded a very clear localization of enzyme activity. The final reaction product (DAB-nickel polymers) in 0.5 - 2.0 microns semithin sections is blue-black; the background staining is completely prevented. An increase of the staining contrast was obtained by posttreatment with OsO4 (osmium black formation). Furthermore, the enzyme reaction product could be demonstrated in 40 nm thick ultrathin sections by silver intensification, which utilized the high argyrophilia of the polymerized DAB-nickel complexes. This procedure replaces the earlier published technique.     

A New and Rapid Method for Making Permanent Aceto-Carmin Smears

Smear the pollen mother cells of a single anther from each flower bud on a clean dry slide, using a small scalpel. Flood the slide with Belling's acetocarmin and heat for a second over an alcohol flame. Examine under the microscope to determine the stage of microsporogenesis. If the stage is satisfactory, smear the remaining anthers in the same manner, but fix and stain them by immediate immersion, face downward, in a petri dish full of hot (steaming) acetocarmin for from 1 to 10 minutes. Then rapidly transfer thru the following mixtures: two parts 99% (glacial) acetic acid plus one part absolute ethyl alcohol; one part acetic acid plus two parts absolute alcohol; and finally one part acetic acid plus nine parts absolute alcohol. The slides are then to be dehydrated completely by 1 to 2 minutes immersion in pure absolute alcohol, and cleared 2 to 3 minutes in a mixture of xylene and absolute alcohol in equal parts. The preparations are then made permanent by mounting each with balsam and a cover glass. The whole process takes from 5 to 15 minutes and is particularly recommended for chromosome counts.     

Conditions necessary for quantifying ethyl methanesulfonate-induced mutations to purine-analogue resistance in Chinese hamster V79 cells.

We have investigated conditions necessary to quantify the relationship between exposure to a mutagen, ethyl methanesulfonate (EMS), and the frequency of mutation induction at the hypoxanthine-guanine phosphoribosyl transferase locus in V79 cells. Maximal expression of potential mutants has been achieved by either subculturing at fewer than 5 X 10(5) cells/100-mm dish at 2-day intervals or by daily feeding of cultures. An expression period of 5 days (measure from 1 day after the initiation of treatment with the chemical mutagen) should be allowed, since at least 4 days of expression is required to reach to steady maximum of mutation frequency. It appears that there is no concentration dependence of expression time necessary to reach a plateau of mutation frequency with increasing concentrations of EMS up to 1.6 mg/ml. About 1.25 X 10(5) cells/100-mm dish or fewer should be plated for selection to avoid the loss of mutants which occurs at 1.5 X 10(5) cells/dish, presumably through cross-feeding (metabolic cooperation). The use of 6-thioguanine in hypoxanthine-free medium (supplemented with dialyzed fetal calf serum) appears to be a very stringent condition for selection. Mutation induction by EMS as a function of EMS exposure (EMS concentration X treatment time) increases linearly with concentration up to 12 h. For these treatment periods, the observed mutation frequencies for EMS are directly proportional to mutagen exposure regardless of the duration of the treatment.     

Protein synthesis requires cell-surface contact while nuclear events respond to cell shape in anchorage-dependent fibroblasts

Anchorage-dependent mouse fibroblasts grow only if attached to and spread on a solid substrate. The suspension of cells in methyl-cellulose results in dramatic, coordinated inhibition of the major RNA and protein synthesis systems, and these systems are sequentially restored when cells are replated on a tissue culture dish surface. In the present report the effects on metabolism of cell reattachment are separated from those of subsequent spreading by controlling cell shape. Macromolecular metabolism is first strongly suppressed by long-term suspension culture. The cells are then replated in the presence of a variety of spreading inhibitors. The recovery of protein synthesis, which rapidly follows reattachment, does not require extensive cell spreading. Contact of a limited portion of the plasma membrane with the solid culture dish surface is apparently a sufficient signal by itself. A very different method of controlling cell shape is afforded by changing culture dish surface adhesivity. Suspended cells are replated on dishes precoated with thin layers of the hydrophilic hydrogen poly(2-hydroxyethyl methacrylate). The final mean cell diameter is then varied over wide limits. As before, protein synthesis recovery is unaffected. However, nuclear events such as DNA and rRNA synthesis and mRNA production are profoundly affected by cell shape. Thus, cell surface contact and cell shape give rise to distinctly different regulatory responses.     

A rapid plastic embedding technique for preparation of three-micron thick sections of decalcified hard tissue.

A 24 hour start-to-finish method is described for the preparation of three-micron-thick sections of decalcified hard tissues. Following acetone dehydration, the tissue to be embedded is infiltrated under vacuum with a series of graded clearing solutions which approach the content of the final methyl methacrylate mixture. After overnight in a 35 C oven, the plastic is polymerized by four hours heating at 42 C. Three-micron-thick sections are then easily prepared by using a Jung microtome for high resolution histologic or detailed autoradiographic procedures.     

Polyolefin matrixes with permanent antibacterial activity: preparation, antibacterial activity, and action mode of the active species

Poly[2-(tert-butylamino)ethyl methacrylate] (PTBAEMA) belongs to a novel class of water-insoluble biocides. Dispersion of a poly(ethylene-co-butylene)-b-poly[2-(tert-butylamino)ethyl methacrylate] diblock copolymer (PEB-b-PTBAEMA) within low-density polyethylene (LDPE) imparts antimicrobial properties to the polyolefin as assessed by the viable cell counting method against Escherichia coli (E. coli). This diblock copolymer has been synthesized by atom transfer radical polymerization (ATRP) with a poly(ethylene-co-butylene) (PEB) oligomer end-capped by an activated bromide as a macroinitiator for the polymerization of 2-(tert-butylamino)ethyl methacrylate (TBAEMA). Morphological changes of E. coli bacteria in contact with modified LDPE have been observed by transmission and scanning electron microscopy and indicate that the diblock copolymer is bactericide rather than bacteriostatic. Finally, the action mode of the PEB-b-PTBAEMA copolymer more likely relies on the displacement of the Ca(2+) and/or Mg(2+) ions of the outer membrane of the bacteria, which is disorganized and finally disrupted.     

Permanent, nonleaching antibacterial surfaces. 1. Synthesis by atom transfer radical polymerization

We have grown an antimicrobial polymer directly on the surfaces of glass and paper using atom transfer radical polymerization (ATRP). The method described here results in potentially permanent nonleaching antibacterial surfaces without the need to chemically graft the antimicrobial material to the substratum. The tertiary amine 2-(dimethylamino)ethyl methacrylate was polymerized directly onto Whatman #1 filter paper or glass slides via atom transfer radical polymerization. Following the polymerization, the tertiary amino groups were quaternized using an alkyl halide to produce a large concentration of quaternary ammonium groups on the polymer-modified surfaces. Incubating the modified materials with either Escherichia coli or Bacillus subtilis demonstrated that the modified surfaces had substantial antimicrobial capacity. The permanence of the antimicrobial activity was demonstrated through repeated use of a modified glass without significant loss of activity. Quaternary amines are believed to cause cell death by disrupting cell membranes allowing release of the intracellular contents. Atomic force microscopic imaging of cells on modified glass surfaces supports this hypothesis.     

Embedding Media for 1-2 Micron Sectioning. 2. Hydroxyethyl Methacrylate Combined with 2-Butoxyethanol

A hydroxyethyl methacrylate monomer medium incorporating 2-butoxyethanol requires 2 stock solutions for embedding. Solution A: 80 ml of hydroxyethyl methacrylate (Rohm and Haas Co., Philadelphia, Pa.) is mixed well with 16 ml of 2-butoxyethanol; 0.27 gm of benzoyl peroxide, the catalyst, is added and permitted to dissolve. Heating to 40-50 C may be used to accelerate its solution. Solution B: polyethylene glycol 200 or 400, 15 parts, and N,N-dimethylaniline, 1 part, are mixed thoroughly. Tissues are dehydrated in the customary manner to absolute ethanol or other comparable dehydrant, infiltrated completely with A, then cast in a mixture consisting of 42 parts of A well mixed with 1 part of B. Polymerizaion occurs in 4-7 hr. In a water bath at 20 C the time required was about 7 hr; at 28 C, 4 hr. This medium is based on the author's water-polyethylene glycol-hydroxyethyl methacrylate monomer medium (Stain Techn., 42: 119-23, 1967).     

A novel chiral separation material: polymerized organogel formed by chiral gelators for the separation of D- and L-phenylalanine

N-Stearine-N'-stearyl-L-phenylalanine, a chiral compound, was synthesized and used as a gelator for the gelation of polymerizable solvents, such as ss-hydroxyethyl methacrylate (HEMA), styrene, etc. The scanning electron microscope (SEM) images of the gelator aggregates show fibril-like helices, typical chiral aggregates with diameters of 100-200 nm. The solvent molecules were immobilized by capillary forces in the three-dimensional network structures of the organogels. The HEMA organogels containing crosslinker polyethylene glycol dimethacrylates (PEG200DMA) were subsequently polymerized by in situ UV irradiation. A porous polymerized organogels were obtained after removal of gelator aggregates through ethanol extraction. The chiral separation of D- and L-phenylalanine was carried out by the adsorption of the polymerized organogels. The adsorption efficiency of L-phenylalanine on the polymerized organogels was found to be dependent on the concentration of the gelator and crosslinker.     

Technic for Studying Chromosome Structure

The methods described are modifications of various technics for the study of spiral structure in chromosomes. They enable permanent preparations to be made with better fixation and allow the use of stains which give clear and more critical definition. The first method described involves the use of ammonium, hydroxide (880 vols.) fumes for the treatment of pollen mother cells before fixation. Anthers of Tradescantia are smeared on a slide and wet in a 3% cane sugar solution. The preparation is then immediately placed in a dish of fixative where it remains for two hours. The slide can then be washed, bleached and stained with gentian violet or hematoxylin. It was found that fumes of nitric acid, hydrochloric acid and glacial acetic acid gave similar results. For the second method, boiling water is used for pre-treatment. A smear is made on a slide and immersed in boiling water for five to ten seconds. The smear is then fixed and treated in the usual manner.     

Inhibition by apple polyphenols of ADP-ribosyltransferase activity of cholera toxin and toxin-induced fluid accumulation in mice

The effects of crude polyphenol extracted from immature apples on the enzymatic and biological activities of a cholera toxin (CT) were investigated. When the apple polyphenol extract (APE) was examined for properties to inhibit CT-catalyzed ADP-ribosylation of agmatine, it was found that APE inhibited it in a dose-dependent manner. The concentration of APE to inhibit 50% of the enzymatic activity of CT (15 microg/ml) was approximately 8.7 microg/ml. The APE also diminished CT-induced fluid accumulation in two diarrhea models for in vivo mice. In the ligated ileum loops, 25 microg of APE significantly inhibited fluid accumulation induced by 500 ng of CT. In a sealed mouse model, even when APE was administered orally 10 min after a toxin injection, fluid accumulation was significantly inhibited at a comparable dosage. Lineweaver-Burk analysis demonstrated that APE had negative allosteric effects on CT-catalyzed NAD: agmatine ADP-ribosyltransferase. We fractionated the APE into four fractions using LH-20 Sephadex resin. One of the fractions, FAP (fraction from apple polyphenol) 1, which contains non-catechin polyphenols, did not significantly inhibit the CT-catalyzed ADP-ribosylation of agmatine. FAP2, which contains compounds with monomeric, dimeric, and trimeric catechins, inhibited the ADP-ribosylation only partially, but significantly. FAP3 and FAP4, which consist of highly polymerized catechin compounds, strongly inhibited the ADP-ribosylation, indicating that the polymerized structure of catechin is responsible for the inhibitory effect that resides in APE. The results suggest that polymerized catechin compounds in APE inhibit the biological and enzymatic activities of CT and can be used in a precautionary and therapeutic manner in the treatment of cholera patients.     

Fabrication of multiresponsive shell cross-linked micelles possessing pH-controllable core swellability and thermo-tunable corona permeability

A double hydrophilic ABC triblock copolymer, poly(2-(diethylamino)ethyl methacrylate)-b-poly(2-(dimethylamino)ethyl methacrylate)-b-poly(N-isopropylacrylamide) (PDEA-b-PDMA-b-PNIPAM), containing the well-known pH-responsive PDEA block and thermoresponsive PNIPAM block, was synthesized by atom transfer radical polymerization via sequential monomer addition using ethyl 2-chloropropionate as the initiator. The obtained triblock copolymer exhibits interesting "schizophrenic" micellization behavior in aqueous solution, and supramolecularly self-assembles into three-layer "onion-like" PNIPAM-core micelles at acidic pH's and elevated temperatures and PDEA-core micelles with "inverted" structures at alkaline pH's and room temperature. In both cases, dynamic laser light scattering (LLS) and optical transmittance reveal the presence of near-monodisperse micelles, and the micelle formation/inversion process is fully reversible. Novel shell cross-linked (SCL) micelles with pH-responsive PDEA cores and thermoresponsive PNIPAM coronas were then facilely fabricated from the PDEA-b-PDMA-b-PNIPAM triblock copolymer by cross-linking the PDMA inner shells with 1,2-bis(2-iodoethoxy)ethane. The reversible pH-dependent swelling/shrinking of PDEA cores and thermosensitive collapse/aggregation of PNIPAM coronas of the obtained SCL micelles were investigated in detail by dynamic LLS, optical transmittance, and transmission electron microscopy. As the structurally stable SCL micelles possess pH-controllable core swellability and thermo-tunable corona permeability, the release profile of a model hydrophobic drug, dipyridamole, initially loaded within the hydrophobic PDEA core, can be dually controlled by both the solution pH and the temperature. This represents the first report of SCL micelles with multiresponsive cores and coronas, which may find practical applications in fields such as drug delivery and smart release.     

Separation of Epoxy-Embedded Cell Cultures from Plastic Flasks for Electron Microscopy

Monolayers of cells grown in ordinary plastic flasks are fixed and embedded “in situ” into Epon. When polymerized at 40 C for 4 days instead of the usual 60 C., the Epon sheet containing the cells is easily detached from the bottom of the plastic container. The Epon sheet is observed by light microscopy as a histological preparation. Ultrathin sectioning of preselected areas can then be carried out in a horizontal plane.