Coumarin in Chromosome Analysis

Root tips of monocotyledons were soaked 2.5-3.0 hours at 25-27° C. in saturated aqueous coumarin solution and stained in a mixture of N HC 1 and 2% aceto-orcein (1:9 by volume) 3-4 seconds over a flame. They were then squashed in 1% orcein under a cover glass, the excess stain blotted and the cover sealed. Preparations could be kept about one week. Good chromosome morphology was secured.     

A Pollen Grain Squash Technique for Saccharum and Related Genera

Anthers collected between 9 and 10 AM were treated for 1 hr at 26-28 C with a 0.5% solution of colchicine, washed for 2-4 min in water, placed in 0.002 M 8-hydroxyquinoline for 1 hr, washed in water for 10 min and fixed in: methanol, 60 ml; chloroform, 30 ml; distilled water, 20 ml; picric acid, 1 gm and mercuric chloride 1 gm, for 24 hr. After washing they were hydrolysed in 1 N HCl for 15 min at 60 C, stained in leuco basic fuchsin for 30 min, then smeared on a slide in a drop of acetocarmine. The slides were sealed, stored overnight, the paraffin was removed, and the slide passed through a 1:1 mixture of n-butyl alcohol and acetic acid, then through pure n-butyl alcohol and mounted in Canada balsam. The significant features of this procedure are: (1) use of chromosomes in the haploid condition for karyotype analysis, (2) better exaggeration of constrictions for easier interpretation of chromosome types and (3) good spreading in plants with a large chromosome number.     

Birth and growth kinetics of brome mosaic virus microcrystals

The early steps of crystal nucleation and growth in Brome Mosa?c virus and polyethylene glycol mixtures were analyzed using time-resolved x-ray scattering (at the European Synchrotron Radiation Facility, Grenoble, France). The system was chosen as a crystallization model since the phase diagram of the macromolecule/polymer mixture was known to present, at high polymer concentration, a solid, precipitated phase made of the synchronized formation of a large number of microcrystals. The precipitation and crystallization of the samples was induced by the controlled mixing of virus and polymer using a stopped-flow device. Appearance and growth of Bragg diffraction peaks were used to follow the crystal nucleation and growth as a function of time, virus and polymer concentration, and polymer size. In all samples, the crystallization starts after a few seconds and proceeds for approximately 1-20 min until there is almost no virus left in the solution. The crystalline system was found to be face-centered cubic, with a unit cell size of 391 angstroms. The data analysis allowed us to show the presence of viruses in only two states, in solution or in crystals, revealing that the formation of periodic order proceeds without any detectable intermediate amorphous state.     

Oxalate solution and collagen-oxalate solution as protective liners for dentine.

The aim of the present study was to evaluate under scanning electron microscopy the ability of different chemically reactive solutions to form a protective layer on dentine. The materials selected were an oxalate solution, a collagen-oxalate solution, a collagen-oxalate solution plus glutaraldehyde and a saline control solution. Small dentine fragments, obtained from extracted human teeth, were treated with the various chemical solution for 60 seconds. All samples were then examined in a Jeol scanning electron microscope. The preliminary observations suggest that dentine may be covered by a mixture of oxalate crystals and collagen producing a homogeneous layer of reactive agents.     

Staining Paraffin Sections with Protargol 6. Impregnation and Differentiation of Nerve Fibers in Adrenal Glands of Mammals

A series of experiments with protargol staining of nerve fibers in mammalian adrenal glands has yielded the following procedure: Fix-1-2 days in a mixture of formamide (Eastman Kodak Company) 10 cc, chloral hydrate 5 g., and 50% ethyl alcohol 90 cc. Wash, dehydrate and embed in paraffin. Cut sections about 15 and mount on slides. Remove the paraffin and run down to distilled water. Mordant 1-2 days in a 1% aqueous solution of thallous (or lead) nitrate at 56-60°C. Wash thru several changes of distilled water and impregnate in 1% aqueous protargol (Winthrop Chemical Company) at 37-40°C. for 1 to 2 days. Rinse quickly in distilled water and differentiate 7-15 seconds in a 0.1% aqueous solution of oxalic acid. Rinse thru several changes of distilled water for a total time of 0.5 to 1.0 rain. Reduce 3-5 rain, in Bodian's reducer: hydroquinone 1 g., sodium sulfite 5 g., distilled water 100 cc. Wash in running water 3-5 min. and tone 5-10 min. in a 0.2% gold chloride solution. Wash 0.5 min. or more and reduce in a 2% oxalic acid solution to which has been added strong formalin, 1 cc. per 100. (Caution. This last reduction is critical and over-reduction can spoil an otherwise good stain; 15-30 seconds usually suffices, and the sections should show only the beginning of darkening to a purplish or gray color.) Wash, fix in hypo, wash, dehydrate and cover.     

Further Studies on a Modification of the Gram Stain

In perfecting the modification of the Gram-stain previously proposed, the following points are of interest:

1. Acetone is too strong a decolorizer for Gram-positive organisms and alcohol too weak for Gram-negative organisms. Consequently, it is now recommended that equal parts of acetone (100% c.p.) and ethyl alcohol (95%) be used as a decolorizing agent. The time of application should not ordinarily exceed 10 seconds.

2. Aqueous basic fuchsin (0.1%) serves as a strongly contrasting counterstain. Prolonged application renders Gram-positive organisms doubtful or Gram-negative, while short application renders Gram-negative organisms doubtful or Gram-positive. Twenty (20) seconds is therefore recommended as the time of application of the counterstain.

3. The method here described, with due regard for its limitations, is of value in Gram-staining pure or mixed cultures as well as for organic materials, such as Acidophilus milk, feces, etc., either for research purposes or classroom use. The method is as follows:

Air-dry film and fix with least amount of heat necessary.

Flood with dye for 5 minutes. Previously mix 30 drops of a 1% aqueous solution of crystal violet or methyl violet 6B with 8 drops of a 5% solution of sodium bicarbonate. Allow the mixture to remain for 5 minutes or more.

Flush with iodine solution for 2 minutes. Two grams iodine dissolved in 10 cc. normal sodium hydroxide solution and 90 cc. water added.

Drain without blotting but do not allow film to dry.

Add a mixture of equal parts of acetone and alcohol drop by drop until the drippings are colorless. (10 seconds or less.)

Air-dry slide.

Counterstain for 20 seconds with 0.1% aqueous solution of basic fuchsin.

Wash off excess stain by short exposure to tap water and air-dry. If slide is not clear immersion in xylol is recommended.     

Cleared Whole Mounts of Shoot Apices of Angiosperms for Topographic Study

Cleared and stained whole mounts of stem apices of two Labiates and of Phaseolus plumule giving a three-dimensional picture of the apical structure have been prepared as follows. Fix the buds in formalin-acetic acid-50% alcohol (5:5:90) for 24 hr or longer and then dissect under a binocular microscope to leave only the youngest leaves surrounding the apex. Wash for several minutes in distilled water and then clear the material in a 5% solution of sodium hydroxide at approximately 40° C for 24-48 hr. Wash thoroughly in several changes of distilled water, transfer to a solution of 1% tannic acid and 0.5% sodium salicylate for up to a minute. Wash briefly in distilled water and stain in a 1.5% solution of ferric chloride until blue-black. Wash in distilled water and dehydrate through 50%, 70%, 85%, 95% and 2 changes of absolute ethyl alcohol. If the xylem is not stained well, counter-stain for a few seconds in a 0.5% solution of safranin O in a 1:1 mixture of xylene and absolute alcohol and wash out the excess stain in the same mixture. Clear in 2 changes of xylene and place on a glass slide in thick Canada balsam. Orient with needles under low magnification and cover.     

The Smear Technic in Plant Cytology

The following method of making permanent smears of pollen mother cells is in general use and gives excellent results. Determine the stage of meiosis from aceto-carmin mounts. Smear the pollen mother cells on a dry slide. Fix in Navaschin's or a modified Flemming's solution from 1 to 2 hours. Wash in 10 to 20% alcohol from 15 to 30 minutes. Stain in 1% aqueous crystal violet from 1 to 5 minutes. Rinse in water and pass thru 30 to 50% alcohol, about 15 to 20 seconds in each. Transfer to 80% alcohol containing 1% iodine and 1% potassium iodide for 30 seconds. Destain with absolute alcohol, followed by clove oil. xylol, balsam and cover.

Permanent smears for chromosome counts can be quickly made by smearing pollen mother cells on a dry slide, fix and stain with aceto-carmin, dehydrate with mixtures of absolute alcohol and acetic acid, follow with xylol, balsam, and cover.     

Staining Paraffin Sections with Protargol: 1. Experiments with Bodian's Method. 2. Use of Jvpropyl and N-Butyl Alcohol in Hofker's Fixative:

Paraffin sections of nervous tissue, which had been fixed in Hofker's fluid, stained readily with protargol solution without the addition of metallic copper or other activator. Amidolsulfite mixtures reduced the protargol more rapidly and completely than hydroquinone-sulfite. Intensification of the stain could be secured by reducing with 0.5% amidol (or pyrogallol) solution after gold toning. The completeness of staining of unmyelinated fibers of the dorsal roots of cat spinal nerves was checked by estimating the number of fibers in a root and the cells of its associated ganglion. A fiber cell ratio of 1:1 was found hi 4 specimens, indicating within limits of error that all fibers were stained. An improvement of die original Hofker's mixture as a fixative was obtained by using a mixture of formic acid, 5 cc.; trichloracetic acid, 10 g.; n-propyl alcohol, 20 cc.; and n-butyl alcohol, 60 cc. (instead of the acetic, trichloracetic, ethyl alcohol mixture used hi the original formula). The following arbitrary method is suggested. Fix 12 to 24 hours, pass to water thru graded ethyl alcohol, wash several hours, dehydrate and embed in paraffin. Cut, mount, and remove the paraffin, pass to water and impregnate 2 or 3 days at 27 to 30$$C. in a 0.5% aqueous solution of protargol (Winthrop Chemical Co.). Rinse 2 or 3 seconds and reduce with 0.5% amidol (Agfa brand used) in 5% sodium sulfite solution. Wash, tone with 0.1% gold chloride, wash and reduce with 0.5% amidol (no sulfite), wash, dehydrate and cover. The method works well on spinal nerve roots, cerebrum, cerebellum, and spinal cord, and moderately well on nerve trunks including sympathetic nerves. Tissues from cat and guinea pig were used.     

A Nuclear Stain for Escherichia Coli And Related Organisms

The dye base of new fuchsin was precipitated by adding potassium hydroxide to the dye solution. The precipitate was filtered out and washed with water. It was then suspended in water, brought into solution and adjusted to a pH of about 5.0 with nitric acid. The staining solution was prepared by adding 0.3 ml. of a 14% aqueous solution of pyrogallol and 0.1 ml. of a 1% aqueous solution of boric acid to 3.0 ml. of the dye solution. Smears of cells were made in water on a slide and allowed to dry before covering with the staining solution which was also permitted to air dry. The smear was then washed in water and mordanted for 5-20 seconds in a 0.1% aqueous solution of mercuric nitrate. After rinsing in water, the smear was air dried. When dry, the slide was placed on a 50° C. warm plate for a few seconds before covering with a very thin film of a 5% aqueous solution of nigrosin which had a pH of about 5.0.     

Effect of elevated temperatures on human lymphocyte chromosomes

The influence of elevated temperatures (38-41 degrees C) on chromosomes of human lymphocytes on different phases of the cell cycle was studied. A high thermosensitivity of chromosomes was demonstrated during (S + G2)-phases of the cell cycle. There was a significant increase in the number of aberrant cells at t greater than 38.5%. The main types of chromosome aberrations were chromatid and chromosome deletions. Cells with 3-5 aberrations and induction of chromosome aberrations due to breaks in the centromere region were noticed at high temperatures (40-41 degrees).     

An Improved Pollen Grain Smear Method for Wheat

Anthers containing actively dividing pollen grains were treated 1 hour at 18-20° C. with 0.2% solution of colchicine, washed 1 hour in water, soaked in 0.002 M aqueous solution of 8-oxyquinoline at 10-14° C. for 1 hour, washed in water for 1 hour and then fixed in Carnoy's solution (alcohol, chloroform, acetic acid, 6:3:1) for 6 hours to overnight. They were washed successively in acetic-alcohol (1:1) 10-15 minutes, 70% alcohol 10-15 minutes and in water 30 minutes before hydrolysing them in bulk in 1 N HCl at 60° C. for 10-15 minutes. “Finally, they were stained in leuco-basic fuchsin for 15-30 minutes. Pollen grains were squeezed out of a stained anther in a small drop of egg albumen on a slide and the albumen smeared uniformly on the slide. The slide was dipped successively for a few seconds in glacial acetic acid and 45% acetic acid respectively. The smear was covered by a cover glass in a drop of aceto-carmine and pressed gently between folded filter papers. The cover glass was sealed with paraffin and stored overnight. To make the preparation permanent the paraffin was removed and the cover glass separated in a 1:1 mixture of acetic acid and n-butyl alcohol. The slide and the cover glass were then passed through n-butyl alcohol, 2 changes, and finally remounted in balsam.     

A Batch Staining Method for Brain Slices Allowing Volume Measurements of Grey and White Matter Using an Image Analyzing Computer (Quanttmet 720)

Normal formalin-fixed gelatin-embedded cerebral hemispheres were serially sliced and the 25 to 30 slices from each hemisphere were batch stained by a modification of Mulligan's method. Following washing in water the slices were immersed in Mulligan's acid/copper sulfate/ phenol solution for 20 minutes at room temperature, treated with a xylene/Polyclens mixture for 20 seconds and immediately transferred to a 2% sodium hydroxide solution for 10 seconds. Final staining was by immersion in 2% potassium ferrocyanide which was followed by washing in tap water. The grey matter was stained a brick red color while the whiteness of the white matter was accentuated. Following staining the slices were stored between sheets of black paper in 2% aqueous formalin prior to measurement of the respective areas of grey and white matter using a Quantimet 720 image analyzing computer. The method is rapid and color stable, and reduces the risk of exposure to toxic fumes by eliminating the need for hot phenol solutions. This technique is also suitable for the macroscopic demonstration and quantitation of demyelinating conditions in the brain.     

Induction of chromosome loss by mixtures of organic solvents including neurotoxins

Twenty-three aprotic polar solvents - 3 nitriles, 8 organic esters, 10 ketones and 2 lactones - and LiCl were tested in combination with propionitrile alone or a mixture of ethyl acetate and propionitrile for the induction of mitotic chromosome loss in the D61.M strain of the yeast Saccharomyces cerevisiae. Propionitrile and ethyl acetate are very potent inducers of chromosome loss. Mixtures of propionitrile and ethyl acetate induced chromosome loss at much higher frequencies than was observed with the pure chemicals. To test the potentiating effects of propionitrile or mixtures of propionitrile with ethyl acetate on other chemicals, they were used in concentrations that were at or below the level for induction of chromosome loss. Twenty chemicals when tested in pure form were negative or only marginally active in the test for chromosome loss. Except for amyl propionate and benzyl acetate, the same chemicals showed strong induction in combination treatments with the potentiating chemicals. All the ketones including the neurotoxic methyl ethyl ketone, 2-hexanone and 2.5-hexanedione induced high frequencies of chromosome loss. Only methyl ethyl ketone is capable of inducing high levels of chromosome loss when tested in the pure form at much higher concentrations. 1-Methyl-2-pyrrolidinone and gamma-valerolactone had previously been shown to induce chromosome loss only when the treatment at a growth-supporting temperature was interrupted by a cold shock within a narrow range of low temperatures which prevented growth. Both gave very strong induction in combination treatment performed at a continuous growth-supporting temperature. LiCl is a weak inducer of chromosome loss: strong induction can be achieved in combination treatments.     

A batch staining method for brain slices allowing volume measurements of grey and white matter using an image analyzing computer (Quantimet 720)

Normal formalin-fixed gelatin-embedded cerebral hemispheres were serially sliced and the 25 to 30 slices form each hemisphere were batch stained by a modification of Mulligan's method. following washing in water the slices were immersed in Mulligan's acid/copper sulfate/phenol solution for 20 minutes at room temperature, treated with a xylene/Polyclens mixture for 20 seconds and immediately transferred to a 2% sodium hydroxide solution for 10 seconds. Final staining was by immersion in 2% potassium ferrocyanide which was followed by washing in tap water. The grey matter was stained a brick red color while the whiteness of the white matter was accentuated. Following staining the slices were stored between sheets of black paper in 2% aqueous formalin prior to measurement of the respective areas of grey and white matter using a Quantimet 720 image analyzing computer. The method is rapid and color stable, and reduces the risk of exposure to toxic fumes by eliminating the need for hot phenol solutions. This technique is also suitable for the macroscopic demonstration and quantitation of demyelinating conditions in the brain.     

Transposition patterns of unlinked transposed Ds elements from two T-DNA loci on tomato chromosomes 7 and 8

We have previously reported that unlinked transposed Ds elements originating from chromosome 4 of tomato preferentially inserted in chromosome 2. This observation, together with data from other studies, suggested that there may be absolute preferences for transposition, irrespective of the chromosomal location of the donor site. The aim of the present work was to verify whether the distribution of transposed Ds elements on chromosome 2 was non-random and thus whether, unlike the case in maize, unlinked transpositions in tomato are not distributed randomly. To do this, unlinked acceptor sites of Ds elements originating from two donor T-DNA loci lying on chromosomes 7 and 8 were mapped. Receptor sites for tr Ds elements transposed from the 1601D locus on chromosome 8 exhibited a non-random distribution (P<0.01). Eleven out of 46 independent transpositions mapped to chromosome 2 and, as this was statistically significant (P<0.01), proves that receptor sites for this element are not randomly distribution on the chromosomes. In addition, deviation of the observed number from the expected number of tr Dss was close to being significant for chromosome 4 (P=0.05-0.1). In contrast, the distribution of unlinked receptor sites for tr Dss derived from the 1481J locus on chromosome 7 was random. Chi(2)tests were performed for each chromosome, and for chromosome 4 the difference between the observed and the expected number of tr Dss was very high but statistically non-significant (P=0.05-0.1). For chromosome 2 the difference was statistically negligible. Therefore, we conclude that chromosome 2 does not serve as a preferential receptor for the transposition of Ds elements independently of the location of the donor site.     

A Staining Method for the Anterior Hypophysis of the Rat

A staining procedure for the anterior hypophysis of the rat, differentiating between eosinophilic granules, basophilic granules and mitochondria, has been divised. Small pieces of hypophyseal tissue are fixed in Champy's fluid. Following fixation the tissue is either chromated or osmicated. After being embedded in 60-62° paraffin, the tissue is cut serially at 2 and 3 μ. The sections are stained with 7% Altmann's acid fuchsin by heating on a laboratory hot plate, followed by 30 seconds in a 2% solution of Orange G made up in 1% phosphomolybdic acid. They are then treated for 10 seconds in a .01% solution of potassium carbonate, and stained for 10-30 minutes in Goodpasture's acid polychrome methylene blue. The mitochondria stain brilliant fuchsia, the eosinophilic granules orange-red, and the basophilic granules deep blue.     

Plasmodesmata in onion (Alliurn cepa L.) roots: a study enabled by improved fixation and embedding techniques

Summary Onion (Allium cepa L. cv. Ebeneezer) roots from vermiculite culture were examined with transmission electron microscopy to detect the plasmodesmata in all tissues. In young root regions, plasmodesmata linked all living cells together in all directions. In old zones, the plasmodesmatal connections of the endodermis to its neighbor tissues were not interrupted by later suberin lamella and cellulosic wall deposition. Moreover, plasmodesmata in the fully mature endodermis usually exhibited a large central cavity. In the exodermis, however, upon deposition of suberin lamellae in long cells, all plasmodesmata that initially linked them to their adjacent cells were severed. Afterwards, the long cells lost the capability of forming wound pit callose and their protoplasts began to degenerate. The mature exodermal layer was symplastically bridged to its neighbors only by the short (passage) cells that lacked suberin lamellae. Compared to the long cells, the short cells not only had thicker cytoplasm surrounding their central vacuoles but also a higher density of mitochondria and rough endoplasmic reticulum, consistent with an active involvement in the transport processes of the root. The above results were obtained by an improved, extended transmission electron microscopy procedure devised to analyze plasmodesmata in cells with suberin lamellae. By prefixing root tissues in glutaraldehyde and acrolein, all cells were well preserved. Postfixation was carried out in osmium tetroxide at a low concentration (0.5%). Following dehydration in acetone and transfer to propylene oxide, infiltration with Spurr's resin was accomplished by incubating samples in the accelerator-free mixture for 4 days, then infiltrating samples in the accelerator-amended mixture for additional 4 days.Abbreviations IE immature exodermis - ME mature exodermis - TBO toluidine blue O - TEM transmission electron microscopy     

Cytological and breeding behavior of pentaploids derived from 3x × 4x crosses in potato

Cytology and breeding behavior of Solanum commersonii - S. tuberosum hybrids derived from 3 x x 4 x crosses was examined. The chromosome number of hybrids ranged from hypo-pentaploid (2 n=5 x - 8=52), to hyper-pentaploid (2 n=5 x + 7=67), with the euploid pentaploid 2 n=5 x=60 class predominant. The high variability in chromosome number of the 3 x x 4 x hybrids was attributed to the fact that meiotic restitution during megasporogenesis of the 3 x female may have involved poles with various chromosome numbers, resulting in 2 n eggs with 24-48 chromosomes. Microsporogenesis analyses provided evidence that chromosome pairing between S. commersonii and S. tuberosum genomes occurred. In addition, chromosome distribution at anaphase I and anaphase II revealed an average chromosome number of 29.5 and 29.1 per pole, respectively. To further study the extent of transmission of extra genome chromosomes from pentaploids, 5 x x 4 x and 4 x x 5 x crosses were performed, and the chromosome number of resulting progeny was determined. Ploidy ranged from 2 n=4 x=48 to 2 n=5 x=60 following 5 x x 4 x crosses, and from 2 n=4 x + 1=49 to 2 n=5 x=60 following 4 x x 5 x crosses. These results provided indirect evidence that the pentaploid hybrids produced viable aneuploid gametes with a chromosome number ranging from 24 to 36. They also demonstrated that gametes with large numbers of extra chromosomes can be functional, resulting in sporophytes between the 4 x and 5 x ploidy level. Fertility parameters of crosses involving various (aneuploid) pentaploid genotypes were not influenced by chromosome number, suggesting a buffering effect of polyploidy on aneuploidy. The possibility of successfully using (aneuploid) pentaploid genotypes for further breeding efforts is discussed.