Staining Protozoa with Janus Green B

The use of janus green to stain mitochondria has long been known. While using it to study the mitochondria in Trichomonas buccalis it was found to stain the flagella also. This is an easy and quick method of determining the number of anterior flagella of the trichomonads and so of distinguishing the trichomonads from the pentatrichomonads in intestinal infections. This stain proved so useful as a flagella stain that it was applied to numerous protozoa with interesting results.     

Stability of the Gram Reaction

In the course of about 7000 examinations of Gram-positive aerobic bacteria, it was found that two distinct groups of Gram-positive organisms could be recognized. One group was illustrated by Micrococcus freudenreichii, the other by Bacillus anthracis. All individuals in a smear of the former remained positive even when the time of exposure to stain was greatly diminished and the time of exposure to decolorizer was greatly increased. Similar changes of technic when B. anthracis was used showed that about 70% of the individuals in a given smear became Gram-negative. The writer accordingly distinguishes between stable and unstable Gram-positive bacteria.     

革兰氏染色三步法与质量控制

革兰氏染色(Gram stain),是细菌学中一个经常使用和十分重要的方法,自从1884年微生物学家Gram氏发明著名的革兰氏染色法以后,100多年来虽然经过后来学者的几次改进,但都仍然沿用着Gram氏原来的四步法,基本原理也没有改变。最近Allen氏对Ziehl-Neelsen抗酸菌染色法的改进,是一个良好的启示,使我们开始了革兰氏染色三步法的研究并取得了成功。现将我们建立的革兰氏染色三步法与质量控制报告如下。 1 材料和方法 1.1 结晶紫染色液 甲液:结晶紫2g;95％乙醇20ml。 乙液:草酸铵0.8g;蒸馏水80ml。 甲乙二液先分别溶解,然后混合在一起,过滤除去残渣后装入滴瓶中备用。     

An Aceto-Carmine Squash Technic for Mature Embryo Sacs

A method is described by which, whole embryo sacs of Nicotiana, Petunia and no doubt of certain other genera can be obtained readily in aceto-carmine ovule squashes. Although application of the technic to megagametogenesis and fertilization stages is stressed in this paper, use of the method allows development to be traced from the archespore up to the second or third division of endosperm nuclei. The success of the technic depends on four phases:-1) fixation in a medium that causes cell and nuclear structures to become pliable, yet rigid enough that their spatial relationships are not greatly distorted in squashing; 2) heat, which apparently increases the cohesion of cytoplasmic and nuclear constituents; 3) maceration to separate the embryo sac from surrounding cells; and 4) the use of a stain that differentiates the various nuclear structures as well as those of the cytoplasm. Staining of the cytoplasm, essential in some embryological investigations, is one advantage of the aceto-carmine squash method over the Feulgen procedure. In contrast to the Feulgen ovule squash method the aceto-carmine technic will probably be most useful in genera having numerous small ovules. Advantages and defects of the aceto-carmine procedure as compared with the paraffin technic are discussed, likewise the possible usefulness of the former in studies of sterility and in certain other special connections.     

Detailed Differentiation of Bacteria by Means of A Mixture of Acid and Basic Dyes at Different pH-Values

As previously reported by the author (1927), a mixture of methylene blue and eosin Y can be used for the differential staining of bacteria. It gives a fairly deep staining of bacteria at about pH 3 and above. Below pH 3 the eosin Y stains bacteria only a very pale pink; at such high H-ion concentration, the eosin is present as undissociated color acid, and for this reason not enough eosin is in solution to stain bacteria. To improve the staining at such reactions, the eosin was replaced by a stronger acid dye, namely acid fuchsin. The mixture of methylene blue medicinal Merck and acid fuchsin can be successfully used at a pH-value as low as 0.8. The method of staining by this new mixture is entirely the same as with the old mixture. It is sensitive enough to detect the difference in the isoelectric points: (1) of the single bacteria from the same pure culture, (2) of different strains of the colon and typhoid organisms. Some strains of the colon organism were found by this method with an isoelectric point at a pH-value as low as that of the Staphylococcus. Others, on the contrary, have their isoelectric point as high in the pH-scale as that of the typhoid organism. The new mixture can also be used for the study of the chemical composition of the different parts of bacterial body. Applying it at a definite pH-value, the author was able to stain differentially polar bodies of the typhoid group and of the diphtheria organism. This new mixture can be recommended in staining of B. diphtheriae as a substitute for Neisser's stain. It is interesting to note that polar bodies of the colon group consist of more alkaline protein than the body of the bacteria itself, i. e., they are stained by acid fuchsin. The polar bodies of the B. diphtheriae on the contrary are composed of more acid protein than the bacterial body; i. e., they are stained by methylene blue. The impossibility of detecting the above mentioned variations in the isoelectric points of bacteria using the Gram method is explained by the absence of pH variations in the latter technic. The differentiation of bacteria by the Gram stain depends chiefly on the varying stability of the compound formed (Gram-positive or Gram-negative bacteria plus gentian violet and iodine) in the presence of organic solvents, such as alcohol, acetone, etc.     

Variability of the Gram Reaction Report of Committee on Bacteriological Technic, of the Society of American Bacteriologists

The results of a cooperative investigation on the Gram stain are reported. One hundred and twenty slides were made by a single technician in one laboratory and distributed to ten collaborators. Each of these slides bore smears of six organisms, which were known to differ considerably from one another in their behavior to the Gram reaction. Identical directions were sent to all those taking part in the work as to how to perform the staining technic.

In regard to four of the six cultures fairly consistent reports were received from all those taking part in the tests. The other two cultures, however, proved so variable in their reaction toward the staining method that it is impossible to consider them either Gram-positive or Gram-negative. Such organisms must be regarded as belonging to an intermediate group, and should be called Gram-variable.

It is pointed out that these results agree with recent work, such as that of Churchman and of Steam and Steam; also that according to the theory of the latter investigators as to the relation between Gram reaction and the isolectric point of the bacteria, no sharp distinction between Gram-positive and Gram-negative organisms could be expected.

These considerations are very important when interpreting results of the Gram technic in the study of pure cultures; but they do not invalidate its use in diagnostic work where it is ordinarily employed to distinguish strongly positive from strongly negative organisms.     

A Method for Staining Certain Bacteria and Antherozoids

A modification of Loeffler's method for staining the flagella of bacteria was employed in staining large forms of bacteria and antherozoids. The bacteria or the antherozoids are killed and fixed in a drop of water on a slide and set aside to dry, before the next step is undertaken. The slide is treated for a period of time, varying from about ten minutes to several hours, in a practically saturated solution of tannic acid. After the slide is thoroly rinsed in water, it is stained with either a single stain or a combination of stains. The slide is then dehydrated with absolute alcohol, cleared, with clove oil, and completed in the usual manner.

The body of the bacterium and that of the antherozoid are well differentiated and the cilia are distinctly brought out by means of the method herein described.

The technic is of especial value in staining the antherozoids of mosses, liverworts, and ferns.     

A simple, rapid method for demonstrating bacterial flagella

We developed a simple, rapid method for demonstrating flagellation of bacteria using the fluorescent protein stain NanoOrange (Molecular Probes, Eugene, Oreg.). The NanoOrange reagent binds to hydrophobic regions of proteins, which results in substantial enhancement of fluorescence. Unbound reagent is essentially nonfluorescent. NanoOrange fluorescently stained bacterial cell bodies, as well as flagella and other appendages, which could be directly observed by epifluorescence microscopy. Detection of flagella was further improved by using a charge-coupled device camera for image capture and processing. The reliability of the method was tested by using 37 pure cultures of marine bacteria. Detection of flagella on the isolates by NanoOrange staining was compared to detection by transmission electron microscopy (TEM). For 36 of 37 cultures, the two methods yielded the same results. In one case, flagella were detected by TEM but not by NanoOrange, although the difference may be attributable to differences between the culture preparations. NanoOrange staining is rapid (10 to 15 min) and does not require fixation or dehydration, so live samples can be stained. Since NanoOrange is a general protein stain and works directly in seawater, it may also prove to be useful for staining other proteinaceous material that is of interest to aquatic microbial ecologists.     

A Simple, Rapid Method for Demonstrating Bacterial Flagella

We developed a simple, rapid method for demonstrating flagellation of bacteria using the fluorescent protein stain NanoOrange (Molecular Probes, Eugene, Oreg.). The NanoOrange reagent binds to hydrophobic regions of proteins, which results in substantial enhancement of fluorescence. Unbound reagent is essentially nonfluorescent. NanoOrange fluorescently stained bacterial cell bodies, as well as flagella and other appendages, which could be directly observed by epifluorescence microscopy. Detection of flagella was further improved by using a charge-coupled device camera for image capture and processing. The reliability of the method was tested by using 37 pure cultures of marine bacteria. Detection of flagella on the isolates by NanoOrange staining was compared to detection by transmission electron microscopy (TEM). For 36 of 37 cultures, the two methods yielded the same results. In one case, flagella were detected by TEM but not by NanoOrange, although the difference may be attributable to differences between the culture preparations. NanoOrange staining is rapid (10 to 15 min) and does not require fixation or dehydration, so live samples can be stained. Since NanoOrange is a general protein stain and works directly in seawater, it may also prove to be useful for staining other proteinaceous material that is of interest to aquatic microbial ecologists.     

Basic Fuchsin as A Nuclear Stain

Five distinct nuclear stains and staining procedures which utilize basic fuchsin as the dye have been studied, compared and tested on a Feulgen-weak fungus, Blastomyces dermatitidis, and other fungi.

Aqueous basic fuchsin has been shown to be an excellent, though impermanent, stain with which to study the nuclei of this and other fungi. The conditions under which formaldehyde acts as a mordant for basic fuchsin and produces a permanent nuclear stain have been established.

Comparison of crystal violet and basic fuchsin suggests that the mordanting action of the aldehyde operates through the para-amino groups of the dye. Certain other basic dyes were not mordanted by formaldehyde.

Gentle acid hydrolysis of the tissues has been found to be essential both to the specificity of the dye as a nuclear stain and to the mordanting effect of the aldehyde.

The possible relationship of these observations to the Feulgen reaction is discussed. A protocol for the method developed is presented.     

Elastin V: Syntheses, Characterization, and Staining Properties of Amidol Black I

One of the monoazo dyes reported by us in an earlier study (Lillie et at. 1972), amidol brown NAP, yielded an oxidation product, amidol black I, which was an excellent elastin stain. The present study revises the synthesis of amidol black I to a more convenient form giving much larger yields. Briefly, diazotized 4-nitro-2-aminophenol is azo-coupled into 2, 4-diaminophenol (amidol) and the product is oxidized to a quinoneimine with nitric. The product stains elastin black from an acid alcohol bath according to a Taenzer-Unna (1890) orcein type technic. The stain may be combined with a Van Gibson collagen stain or with an oil red O fat stain. The synthesis is presented in sufficient detail to permit its repetition in a hospital pathology laboratory.     

A Carmine-Giemsa Staining Technic For Meiotic Prophase Chromosomes Of The Genus Beta L

For a detailed study of chromosome morphology in meiotic prophase stages of Beta species, a special double staining technic has been developed. It consists of combined maceration-staining in an ethanol-hydrochloric acid-carmine mixture followed by poststaining of the squashed material in a diluted Giemsa solution. The technic yields well-spread prophase meiotic nuclei showing detailed structures both in weaker stained chromosome segments and in threadlike chromatin structures. This technic proved to be especially favorable for stages which are difficult to interpret, such as pachytene, schizotene and diffuse stages.     

An Improvement in Staining Technic for Protozoa

A modification of Donaldson's iodine-eosin stain for staining intestinal protozoa is presented. This modification consists of using high dilutions of colloidal iodine (Chandler)² instead of Lugol's solution as well as high dilutions of eosin. A better resolution of the external and internal structures is brought about by the new method.

The procedure is as follows: A portion of the fecal material to be examined is suspended in a 0.6% salt solution; the suspension should be of a consistency so that one drop will make a satisfactory microscope mount under a cover glass. To ten parts of this suspension, in a test tube, is added one part of the stain which is prepared as follows:—

10 parts of distilled water

6 parts of a suspension of colloidal iodine (Chandler) containing 4% iodine—20% iodine suspensoid, Merck

1 part of a 10% water solution of anilin red, Merck (eosin yellowish)

Technicians will find, because iodine in the form of colloidal iodine is readily released to the organisms, that the use of this material is far superior to Lugol's solution hi carrying out the technic for staining intestinal protozoa in the study of fresh mount preparations. Not only are organisms more deeply stained with iodine but by eosin as well, even when employed in high dilutions.     

The Use of Sudan Black B as a Bacterial Fat Stain

Sudan black B was introduced as a specific fat stain for the detection of lipids in tissue sections by L. Lison in 1934. Saturated solutions of Sudan black B in 70% alcohol or in ethylene glycol stain the fat bodies of bacteria a deep blue-black color, and this dye is recommended as superior to the other Sudans.

The method used in staining the bacteria was to suspend a loopful of the cells in a drop of the stain solution and to prepare flat wet mounts. The organisms giving positive fat tests with Sudan black B included Bacillus cereus, Bacillus mycoides, Azotobacter beijerinckii, Rhizobium leguminosarum, Mycobacterium avium, Mycobacterium leprae, Oospora lactis, Bacillus tumescens, water spirilla, and fungi.     

A Note on the Gram Stain

A modification of the Gram stain in which iodine-alcohol is substituted for 95% alcohol as a decolorizing agent has been found particularly useful in staining Gram-positive organisms in tissues and also for smears. The technic for tissue sections follows:

1. Apply nuclear stain.
2. Wash.
3. Stain in Hucker's gentian violet 2 to 3 minutes (i. e. 1 part Sat. Alc. Sol. crystal violet to 4 parts 1% Aqu. Sol. ammonium oxalte).
4. Wash in water.
5. Stain in Gram's iodine 5 minutes.
6. Wash in water.
7. Decolorize in 95% alcohol to which enough tincture of iodine has been added to give a mahogany color.
8. Counterstain.
9. Dehydrate and mount.

     

Variability of the Gram Reaction Report of Committee on Bacteriological Technic,of the Society of American Bacteriologists

The results of a cooperative investigation on the Gram stain are reported. One hundred and twenty slides were made by a single technician in one laboratory and distributed to ten collaborators. Each of these slides bore smears of six organisms, which were known to differ considerably from one another in their behavior to the Gram reaction. Identical directions were sent to all those taking part in the work as to how to perform the staining technic.

In regard to four of the six cultures fairly consistent reports were received from all those taking part in the tests. The other two cultures, however, proved so variable in their reaction toward the staining method that it is impossible to consider them either Gram-positive or Gram-negative. Such organisms must be regarded as belonging to an intermediate group, and should be called Gram-variable.

It is pointed out that these results agree with recent work, such as that of Churchman and of Steam and Steam; also that according to the theory of the latter investigators as to the relation between Gram reaction and the isolectric point of the bacteria, no sharp distinction between Gram-positive and Gram-negative organisms could be expected.

These considerations are very important when interpreting results of the Gram technic in the study of pure cultures; but they do not invalidate its use in diagnostic work where it is ordinarily employed to distinguish strongly positive from strongly negative organisms.     

A Modified Wright's Method for Staining Blood Smears

After the blood smear is treated for the proper length of time with Wright's stain, neutral distilled water is used for diluting the stain. After the slide has been treated with neutral distilled water until the smear becomes pinkish it is then treated with pure absolute methyl alcohol which destains the plasma. Neutral distilled water is again kept on the mount until the corpuscles are well stained. Then the slide is dehydrated with absolute ethyl alcohol, cleared with clove oil and completed in the usual way.

Blood smears of different groups of vertebrates were uniformly brilliantly stained with the above technic.

Several lots of Wright's dry stain have been tested with the modified technic and no difficulties have been encountered in its application.     

Aceto-Iron-Haematoxylin for Staining Chromosomes in Squashes of Plant Material

Haematoxylin can be used successfully in the acetic squash technic if adequate mordanting is provided, (a) in the stain—composed of 4% haematoxylin and 1% iron alum in 45% acetic acid—and (b) in a step that combines additional fixation, mordanting and maceration in a 1:1 HCl-alcohol mixture, to which is added chrome alum, iron alum and iodic acid: 0.1 gm of each to 6 ml of HCl-alcohol. The material is usually given a preliminary fixation in 1:3 acetic alcohol, then macerated, fixed and mordanted in the acidified alum-HIO₃ step for 10 min, transferred to Carney's fluid (6:3:1) for 10-20 min, squashed in a drop of stain and gently heated. In some species, the preliminary fixation may be omitted. The method yields intensely and selectively stained chromatin. To secure consistently good results, the stain can be diluted with 45% acetic acid, and the iodic acid omitted for some plant materials.