A Hematoxylin Staining Procedure for Maize Pollen Grain Chromosomes

Studies of postmeiotic chromosome behavior have been impeded by the thick exine and abundant starch grains of maize pollen. Staining pollen grain chromosomes with acetocarmine is tedious and gives inconsistent, often unsatisfactory results. A hematoxylin stain, used in conjunction with the clearing agent chloral hydrate, has been successfully used by the authors to stain chromosomes, nuclei and sperm cells of the maize pollen grain. An ethanol-formaldehyde fixing fluid is used to fix and preserve the pollen samples. The procedure, which is rapid and simple, gives excellent preparations with both fresh and fixed material. Stained preparations do not get darker with time, as is typical of other hematoxylin stained materials.     

Recent Advances in Microtechnic. I. Methods of Studying the Development of the Male Gametophyte in Angiosperms

Among methods used for a study of nuclear details in the development of pollen grains, the following were found to be very satisfactory: (1) warming the entire grains in aceto-carmine and then clearing with chloral hydrate; (2) making smear preparations stained with crystal-violet-iodine or iron alum hematoxylin. For paraffin sections, a counterstain with dilute alcoholic erythrosin is often very useful after the usual iron hematoxylin technic.

A method of making cultures of pollen tubes on slides coated with thin films of sugar agar is described in detail. The tubes can be fixed by immersing the slide in formol-acetic-alcohol and then stained by any desired schedule. Iron alum hematoxylin was found to be the most satisfactory, but the Feulgen reaction is very valuable in such cases where the nuclei are obscured by the density of the pollen tube cytoplasm. Living pollen tubes can be kept under observation by dissolving a small quantity of neutral red or other vital stain in the sugar agar before it is spread on the slide.

For studying stages in fertilization or gametogenesis, styles should be fixed and sectioned only after a preliminary study with iodine-chloral-hydrate or safranin-anilin-blue or aceto-carmine. Once the extent to which pollen tubes grow in a given time in the stylar tissues has been determined, it is possible to fix material with some knowledge of what it is going to show.

Some other methods, that have not been tried by the authors but appear to be valuable, are also briefly described.     

Delineation of human chromosome contour by heat treatment and hematoxylin staining

An unusual form of staining was observed as a result of heat treatment: chromosome contour became easily recognizable. Chromosome contour is optimally delineated by heat treatment of metaphase preparations in 0.06 M phosphate buffer, pH 6.8–7.0 at 95° C for 10 min, and subsequent staining with Heidenhain's hematoxylin. This result is obtained by a process similar to that in which Giemsa has been reported to stain particular foci considered to represent selective staining of constitutive heterochromatin. Mordanting with 3% ferrous ammonium sulfate produced maximum staining. However, hematoxylin (Harris) also stained the periphery of chromosomes. A transitional temperature existed between 70° C and 80° C in which contour became evident. When metaphase preparations were heated at 90–95° C, contour occurred on some chromosomes within 3 min and was demonstrated in 100% of the chromosomes analysed after 10 min of heat treatment.Supported in part by a grant to C. Romero-Sierra from the Defence Research Board of Canada (DRB 9350-24) and to E. A. MacKinnon from the Medical Research Council of Canada (MA-4135).     

The long history of hematoxylin

Hematoxylin is a naturally occurring chemical used as the basis of a dye in laboratories throughout the world to stain nuclei in microscope slide preparations. This chemical is extracted from the logwood tree Hematoxylon campechianum and was discovered by Spanish explorers to the Yucatan in 1502. A vigorous trade soon developed related to growing and preparing hematoxylin for use in dyeing fabrics in Europe. In the mid 1800s, amateur microscopists first used hematoxylin to stain cellular components. Later scientists developed a wide range of techniques to demonstrate different cellular components. Hematoxylin remains the most popular nuclear stain in histology. This paper briefly describes the history of hematoxylin production and use in histology.     

Chromatin in diapause of the silkworm Bombyx mori L.: thermal parthenogenesis and normal development

Having used hematoxylin as a stain, some features of silkworm embryo chromatin in diapause have been studied in normal and parthenogenetic development. With found direct correlation between the number of interphase chromatin grains and the number of chromosomes in the nucleus, we examined cell polyploidization in the embryo at diapause stage. Polyploidization by parthenogenesis is not reducible to endomitotic doubling of the chromosome set because it comprises 6n-nuclei. Explanation of more diverse range of polyploid cells in parthenogenesis needs to consider the fusion of cleavage nuclei that is carried out by the cytoplasmic karyogamic mechanism in the absence of fertilization. For the first time on squash preparations, in diapausing embryo, we have identified primary germ cells (PGC) that are characterized by less compact chromatin, especially in the zygotic form of development, a larger size of the nucleus and cytoplasm, and irregular number and size of nucleoli. Evaluation of PGC ploidy in parthenogenesis by calculation of "loose" chromatin grains in diapause is possible and testifies polyploidization in embryo germ-line. This explains the inevitable admixture of tetraploid eggs in diploid parthenoclone grain and its absence in normal development. Cytological method used has revealed a spiral arrangement of chromatin grains on the inner surface of the nucleus at different levels of ploidy.     

The long history of hematoxylin

Hematoxylin is a naturally occurring chemical used as the basis of a dye in laboratories throughout the world to stain nuclei in microscope slide preparations. This chemical is extracted from the logwood tree Hematoxylon campechianum and was discovered by Spanish explorers to the Yucatan in 1502. A vigorous trade soon developed related to growing and preparing hematoxylin for use in dyeing fabrics in Europe. In the mid 1800s, amateur microscopists first used hematoxylin to stain cellular components. Later scientists developed a wide range of techniques to demonstrate different cellular components. Hematoxylin remains the most popular nuclear stain in histology. This paper briefly describes the history of hematoxylin production and use in histology.     

The Use of Haematoxylin for Squash Preparations of Chromosomes

A simplified propionic-iron alum-haematoxylin stain for rapid squash preparations of chromosomes requires only two stock solutions: (A) 2% haematoxylin and (B) 0.5% iron alum, both in 50% propionic acid. For use, suitable volumes of A and B are mixed. With unripened solution A, equal volumes should be used and the stain is ready for use 1 day after mixing. As the haematoxylin ripens, progressively smaller amounts of B are required and the mixture may be used immediately. The stain gives excellent results when used in the same way that orcein and carmine are currently employed, with a wide range of animal and plant (including fungal) chromosomes, and with good nucleolar staining. It may be used either following acetic alcohol (1:3) fixation or as joint fixative and stain on unfixed material. In fungal material, where Lu's BAC fixative is recommended, the centrioles are also stained.     

The Use of Lacto-Propionic Orcein in Rapid Squash Methods for Chromosome Preparations

A solution of 2 gm of natural orcein dissolved in 100 ml of a mixture of equal parts of lactic and propionic acids, and diluted to 45% with water, proved more effective than other stain fixatives for meiotic preparations from fresh pollen mother cells. When used after 5 min fixation in modified Carnoy's fixative (alcohol, acetic acid, chloroform, formalin; 10:2:2:1) and 5 min maceration in 1 N HC1 at 60° C, the same stain proved the most suitable for the rapid preparation of root-tip chromosomes for counting and for studying detailed morphology.     

Double fertilization in maize: the two male gametes from a pollen grain have the ability to fuse with egg cells

In flowering plants, two male gametes from a single pollen grain fuse with two female gametes, the egg and central cells, to form the embryo and endosperm, respectively. The question then arises whether the two male gametes fuse randomly with the egg and central cells. We investigated this question using two nearly isogenic maize lines with supernumerary B chromosomes (TB10L18) or without (r-tester). B chromosomes regularly undergo non-disjunction at the second pollen mitosis, producing one sperm cell with zero B chromosomes and one with two. We first confirmed earlier studies showing an excess of transmission of the B chromosomes to the embryo rather than to the endosperm. We then tested the possibility of a directed fertilization. For TB10L18 pollen, we could demonstrate the existence of a size dimorphism between the two sperm cells, correlated to the content in B chromosomes, as detected by fluorescence in situ hybridization (FISH). However, no directed fusion of B chromosome containing sperm to egg cells could be detected when using in vitro fertilization. The absence of directed fusion in vitro could also be demonstrated for control lines. We conclude that both male gametes have the capacity to fuse with the egg cell in maize, although sexual reproduction results in a preferential transmission of supernumerary B chromosomes.     

Induction of G-bands in Root Tip Chromosomes of the Maize

Authors tried to induce G-bands of chromosomes of root-tips in maize (Zey mays L.. everty Sturt) with a variety of technological modifications. The following techniques were found to be more satisfactory: primary root-tips were treated with an aqueous actinomycin D(AMD) solution (70 μg/ml) at room temperature; air dry slides of chromosomes in maize made the chromosomes spread well and plasma off; and then the preparations of the chromosomes were treated with modified methods of Seabright[7] and Utakoji[8] and the technique of aceto-orcin stain. The G-bands of chromosomes of corn were induced with the three methods above. They were shown in Plate 1, 2, 3 and 4 which are similar to the G-bands of chromosomes in human and mammal, and these bands are more consistent in each chromosomes.     

Heidenhain's Hematoxylin Used with the Smear Technic

Heidenhain's hematoxylin, according to the following formula, may be used for studying chromosomes in temporary smears of pollen mother cells: 1 part 0.5% hematoxylin and 4% iron-alum (equal parts of each); 1 part 95% alcohol; and 2 parts glacial acetic acid.     

Naked Oat×Maize Hybridization

There is a certain frequency of fertilization and embryo productivity in naked oat (Avena nuda L. ) × maize (Zea mays L. ) crosses. The maize pollen readily germinated on the naked oat stigma and more than one pollen tubes grew into the style in about 68% of florets. In a sample of 163 florets fixed after pollination, 5 (3.07%) had only an embryo, 3 (1.84%) had only an endosperm and 10 (6.13%) had both. Overall, 9 haploid and 3 diploid naked oat plants were obtained from 12 seeds which formed following application of maize pollen to about 2200 emasculated naked oat florets. Preliminary studies indicated that elimination of the maize chromosomes occurred early in the embryo and endosperm development. This method gives a new approach for obtaining haplo!d naked oat.     

A simple procedure for obtaining autoradiographs of G-banded chromosomes

Chromosomal preparations from cells flash-labeled with ³H-dT were Giemsa-banded following trypsin digestion, allowed to air-dry, and then were coated with a layer of 1% Formvar. The slides were subsequently coated with radiographic emulsion (NTB2) and processed for autoradiography. The resulting chromosomes had distinct G-banding and radiographic labeling patterns. Chemographic grain formation in the emulsion, normally caused by Giemsa stain, was prevented by the film of Formvar, allowing a very low background grain level.     

B Chromosome Behavior in Maize Pollen as Determined by a Molecular Probe

The B chromosomes of maize typically undergo nondisjunction during the second microspore division (generative cell division). When the microspore nucleus contains only one B chromosome, two kinds of sperm result, one with two B chromosomes and one with no B chromosomes. The sperm with the B chromosomes preferentially fertilizes the egg cell. Previous studies of these phenomena have been limited to genetic analysis and chromosome spreads. In this study we show that a B chromosome-specific probe can be used with fluorescence in situ hybridization (FISH) analysis to detect the presence, location, and frequency of B chromosomes in intact interphase nuclei within mature pollen of maize. Using genetic line TB-10L18, our results indicate that nondisjunction of the B centromere occurs at an average frequency of 56.6%, based on four plants and 1306 pollen grains analyzed. This is consistent with the results of genetic studies using the same B-A translocation. In addition, our results suggest that B chromosome nondisjunction can occur during the first microspore division. Spatial distribution of the B chromosome-specific probe appears to be largely confined to one tip of the sperm nucleus, and a DNA fragment found outside the pollen nuclei often hybridizes to the B chromosome-specific probe.     

A Method for Combined C-Banding and Silver Staining

A reliable technique for combined C-banding and silver staining of metaphase chromosomes which uses trypsinization is described. Slides are first immersed in dilute HCl to remove residual cytoplasm from around the chromosomes. They are then treated with saturated barium hydroxide and incubated overnight in saline sodium citrate (0.30 M NaCl, 0.03 M sodium citrate, adjusted to pH 7.0 with HCl). Following the C-banding pretreatment, a two-step method of silver staining which employs a protective colloidal developer is used to stain the nucleolar organizer regions (NORs) of the chromosomes. Silver staining is followed by trypsinization to remove extraneous silver precipitate from the chromosome arms which permits the C-bands to be stained with Giemsa. The method works equally well with fresh and aged mitotic chromosome preparations and gives consistent staining of both heterochromatin and active NORs in metaphases across the slide.     

A method for combined C-banding and silver staining

A reliable technique for combined C-banding and silver staining of metaphase chromosomes which uses trypsinization is described. Slides are first immersed in dilute HCl to remove residual cytoplasm from around the chromosomes. They are then treated with saturated barium hydroxide and incubated overnight in saline sodium citrate (0.30 M NaCl, 0.03 M sodium citrate, adjusted to pH 7.0 with HCl). Following the C-banding pretreatment, a two-step method of silver staining which employs a protective colloidal developer is used to stain the nucleolar organizer regions (NORs) of the chromosomes. Silver staining is followed by trypsinization to remove extraneous silver precipitate from the chromosome arms which permits the C-bands to be stained with Giemsa. The method works equally well with fresh and aged mitotic chromosome preparations and gives consistent staining of both heterochromatin and active NORs in metaphases across the slide.     

Sperm Identification in Maize by Fluorescence in Situ Hybridization

The two sperm cells of common origin within the pollen tube of flowering plants are each involved in a fertilization event. It has long been recognized that preferential fusion of one sperm with the egg can occur in B chromosome-containing lines of maize. If the second pollen mitosis begins with a single B chromosome, nondisjunction will result in one sperm possessing two B chromosomes and the other containing no B chromosomes. The B chromosome-containing sperm most often fertilizes the egg, whereas the sperm nucleus with no B chromosomes fuses with the polar nuclei. Despite the obvious advantages of being able to recognize and then track, separate, and analyze one sperm type from the other, it has not been possible because of the lack of sufficient detectable differences between the two types of sperms. In this study, we used a B chromosome-specific DNA sequence (pZmBs) and in situ hybridization to identify and track the B chromosome-containing sperm cell within mature pollen and pollen tubes. Our results are consistent with conclusions from previous genetic studies related to B chromosome behavior during pollen formation. Within pollen tubes, the position in which the B chromosome-containing sperm travels (leading or trailing) in relation to the sperm cell lacking B chromosomes appears to be random.     

A simple method for staining nuclei of mature and germinated maize pollen

A sugar acetocarmine staining technique has been developed for staining the sperm and vegetative nucleus of mature and germinated maize pollen grains. This procedure is simple, stable and highly repeatable. The physiological properties of the mature maize pollen grains are first adjusted by using an in vitro germinating culture solution. This solution is 15% sucrose and contains 360 ppm calcium chloride dihydrate, and 120 ppm boric acid. One part fresh pollen grains is uniformly mixed with nine parts of the solution and left at room temperature for at least 5 hr. One part of this solution is then mixed with two parts of regular acetocarmine stain and left overnight. The color of this mixture is pinkish red or raspberry. The sugar in the mixture helps to increase color contrast between the pollen cytoplasm (light pink) and the nuclei (reddish purple), decreases the frequency of burst pollen, increases pollen expansion, stabilizes pollen figures and automatically seals the coverglass.     

Cytogenetical Changes among Polyembryonic (PEm) and Non-PEm Maize Plants

Polyembryony in maize (PEm) contributes to improving the nutritional properties of the grain, as well as an increase in yield, since it generates multiple plants per seed, opening the possibility of developing new varieties. However, it is unknown whether polyembryony in maize is the product of chromosomal abnormalities. Based on the above, in this research a cytogenetic study was proposed to verify if chromosomal abnormalities are related to the maize polyembryony. For a meiotic study, maize genotypes with variable proportions of polyembryony (PEm), from the UA-IMM-BAP population and non-PEm (monoembryonic) maize were used, while for a mitosis analysis, 30 families of maternal half-siblings (MHS) from two different populations with high polyembryony, denominated as BHP (brachytic, high polyembryony) and NHP (normal height, high polyembryony) were used. All these genotypes were planted in the Buenavista Agricultural Experimental Station-UAAAN at Saltillo, Coahuila, Mexico. The frequency of PEm was estimated in all genotypes. It was found that the polyembryony occurs at frequencies from 34 to 66% in the D-02, BHP group, and from 13 to 21% in the segregating groups of the G3-0202 and G3-0201. The squash technique was used for both cytogenetic analyses. Different meiotic irregularities in maize chromosomes were detected, such as irregular association of 10% of chromosomes in metaphase 1, and agglomeration of chromatin in 100% of the cells. In addition, pollen viability was estimated by the staining technique with 1% acetocarmine dye, and it was found that the polyembryonic ones have pollen viability of 100%. In meiosis in prophase, I sub-phase diakinesis, ten pairs of bivalents were confirmed, confirming 2n = 20, both in non-PEm and PEm maize, corroborating mating, and balanced segregation, without the presence of univalent or multivalent. In the chromosomal count carried out in cells in mitosis, only in the BHP-200 polyembryonic family was registered two out of twenty triploid plants. This condition of ploidy is atypical in maize, so it is recommended to analyze more plants from this family.