A methodological study for the quantification and the control of the physico-chemical processes occurring during cell fixation

Summary Fixation in a traditional sense means the immersion of biological material into a chemical fluid. For permanent preservation the fixative is always offered (1) in excess of the cell sample, and the process of fixation is influenced by (2) chemical impurities of the fixative fluid.Both factors influence the succeeding dyeing of cells. In order to avoid these uncontrolled criteria, a new technology for controlled cell fixation has been developed, whereby freshly prepared formaldehyde and methanol gas in an inert gas-flow of helium was applied to thin membranes by aid of a capillary flow-in technique.The instrumental equipment consists of (1) an ultra-high vacuum flowapparatus with a total-pressure measuring unit, (2) a gas-supply device, (3) a mass spectrometer including a pump system, and (4) a Teflon and/or glass-gas chamber for the treatment of synthetic (Hostaphan foils) or biological membranes (mesenterium) with formaldehyde as the fixative gas.The amount of offered, adsorbed, absorbed, diffused, and desorbed fixative gas could be absolutely estimated after the saturation of the membranes with an on-line operating inert mass spectrometer of the Omegatron type.The gas treatment of the Hostaphan foils with formaldehyde showed that nearly all adsorbed gas molecules could be desorbed. In contrast to native membranes the greatest proportion of the gas molecules adhered to the biological surface, and only a small quantity were desorbable. Physisorption or physisorption and chemisorption occured depending on the adsorber surface property.A monolayer of formaldehyde of 5·10¹⁴ to 1·10¹⁵ molecules per 10¹⁶ Ų surface area can be postulated on the basis of these preliminary results. This value corresponds to a mass of about 5·10^–8g CH₂O. It resulted in an area-coverage ratio of CH₂O molecules per cell of 10⁹:1.The membrane surface facing the gas side always amounted to 1 cm². A fixative gas concentration of 10⁶ molecules/cm³, and therefore a degree of coverage of <1/1000 monolayer can be estimated absolutely. For a precise determination of the degree of fixation, further experiments and the evaluation of additional physico-chemical parameters are necessary.     

The development of a new technology for controlled cell fixation. A methodological pilot study.

Fixation in a traditional sense means the immersion of biological material into a chemical fluid. For permanent preservation (1) the fixative is always supplied in excess of the cell sample, and (2) the process of fixation is influenced by chemical impurities of the fixative fluid. Both factors influence the subsequent staining of cells. In order to avoid these uncontrolled influences, a new technology for controlled cell fixation has to be developed, whereby freshly prepared formaldehyde gas in an "inert" gas-flow of helium was applied to thin membranes by use of a capillary flow-in technique. The amount of fixative gas supplied, adsorbed, absorbed, diffused, and desorbed after saturation of the membranes could be reliably measured with an on-line operating "inert" mass spectrometer of the Omegatron type.     

Improved utilization of tissue blocks for electron microscopy. Effect of various concentrations of formaldehyde and glutaraldehyde.

Liver tissue from miniature pig fetuses was immersion-fixed in fixative mixtures with various concentrations of formaldehyde and glutaraldehyde. The preservation quality of hepatocytes was evaluated ultrastructurally in a peripheral zone (30--130 micron below the surface) and a central zone (500 micron below the surface). In the peripheral zone the best preservation was obtained with a fixative mixture containing 2% formaldehyde and 2% glutaraldehyde and in the central zone with a fixative mixture containing 8% formaldehyde and 8% glutaraldehyde. It is concluded that a better utilization of fairly large tissue blocks for ultrastructural investigation can be obtained by division of the block and subsequent fixation in fixatives containing various concentrations of formaldehyde and glutaraldehyde.     

Effects of Ph on Post-Mortem Retention of Trypan Blue Vital Staining in Tissues of Mice

Vital staining of aortas from mice injected subcutaneously (daily for 5 days) with trypan blue was studied. In routine paraffin sections elastic membranes were observed to be well stained and other medial elements unstained following fixation in 10% formaldehyde (25% formalin) at pH 7-9. An identical pattern of vital staining was observed in specimens that had been immersed for 48 hr in saline solutions at pH 7-11. Elastic membranes were not stained, but intermembranous connective tissue was stained after the following: (1) fixation in 10% formaldehyde at pH 1-4 and in Lavdowsky's solution (ethanol, formaldehyde, water and glacial acetic acid), pH 2.3-2.8; and (2) immersion in saline for 48 hr at pH 14. Aortic elastic membranes were vitally stained after fixation by intracardiac perfusion with 10% formaldehyde (pH 7-8) but not after perhion with Lavdowsky's fixative (pH 2.3-2.8). Vital staining was limited to medial elastic membranes in sections of fresh aorta made in a cryostat or by a regular freezing microtome. The vital staining (coarse cytoplasmic granules of dye) within macrophages (Kupffer cells and others) and in cytoplasm of renal tubular epithelium was well demonstrated following use of all methods discussed above     

Some aspects of the Feulgen reaction in situ

Summary Cytological observations combined with studies on absorption spectra of Feulgen stained normal and lipid — extractet HeLa and ehrlich-Lettré mouse ascites cells were performed after fixation of the cells as well in neutral formaldehyde as in Serra fixative. The effects of formaldehyde treatment of the stained cells to substitute all the free amino groups of DNA bond pararosaniline molecules, were also studied. The results obtained by using DNA samples containing 2% protein and relatively free from protein, led to the conclusion that after acid hydrolysis for a short period purines in DNA become splitted and these released aldehydes react with one or two amino groups of pararosaniline, a triphenylmethane dye (according to the arrangement of purines and pyrimidines in the helices). Some protein molecules also take part in the reaction and substitute some of the free amino groups of DNA bound pararosaniline. Peulgen stained cells fixed in Serra fixative show an absorption maximum at 546–550 m. Under appropriate conditions, as in cells fixed in formaldehyde, other substances e.g. phospholipids and lipoproteins interfere with the reaction by substituting most of the free amino groups of DNA bound pararosaniline molecules. It has been argued that in histochemical reactions monosubstituted pararosaniline molecules should be coloured and further substitution of free amino groups of pararosaniline, bound in DNA helices, does not change the intensity of the colour, but gives a shift in the wavelength of the absorption spectra.It has been suggested that the differential response of the nucleoli to the Feulgen-reaction, depending on whether the cells were fixed in formaldehyde or in Serra fixative, may be due to the formation of a protecting shield around the finely distributed intranucleolar chromatin strands, when formaldehyde is being used. After this fixation lipoproteins and other lipids, present in a relatively high percentage and closely associated with the intranucleolar chromatin strands, are especially well preserved.Evidences have been put foreward in support of the amino alkylsulfonic acid theory of Rumpf (1935) and Hörmann et al. (1958) whereas the amino sulfinic acid theory to explain the Schiffs reaction (Wieland and Scheuing, 1921) was shown not to be in agreement with our results.On leave from the Department of Botany, Calcutta University, 35, Ballygunge Circular Road, Calcutta-19, India; on a fellowship from the German Academic Exchange Service.     

A Comparison of Fixation by Formaldehyde and Glutaraldehyde-Formaldehyde for Combined Light and Electron Microscopy of Axonal Degeneration in the Mammillary Body

Mammillary body (Mb) cell structures were compared following four different procedures for fixation, in order to find one procedure which would be suitable both for silver impregnation methods and electron microscopy. Fixatives compared were: (1) formaldehyde (4% pH 5.5), Mb from a frozen-section; (2) formaldehyde (4% pH 7.2.), Mb from a frozen-section; (3) glutaraldehyde-formaldehyde (1%-4% pH 6.0), Mb from a frozen-section; and (4) glutaraldehyde-formaldehyde (3%-2% pH 7.2), unfrozen Mb. All solutions were perfused into the left ventricle of the heart of anesthetized rats, except for the animal from which the unfrozen tissue was obtained. The Mb was excised from the fresh brain and immediately placed in a fixative solution. After aldehyde fixation, the tissues were further fixed in 1% OsO₄ (pH 7.4), dehydrated, embedded in Epon-Araldite and double-stained with uranyl acetate and lead citrate. Comparisons of mitochondria, myelin, synapses, neurofilaments and synaptic membranes indicated that the perfusion of 4% formaldehyde is suitable for both electron microscopy and silver impregnation, and was preferable to the other fixatives tested.     

Importance of fixation in immunohistochemistry: use of formaldehyde solutions at variable pH for the localization of tyrosine hydroxylase

Adequate fixative in immunohistochemistry requires not only a rapid and total immobilization of the antigen, but also a sufficient preservation of its immunoreactivity and maintenance of its accessibility to the immunochemical reagents for localization. Thus, the optimal fixation condition for a specific antigen necessitates a compromise between these opposing variables and can be determined by the preparation of a series of tissues with a progressively increasing degree of fixation. Unless the results of localization using such a series is available, one must be satisfied with adequate but less than optimal results. In the present study, this principle is demonstrated using the localization of tyrosine hydroxylase in the dopaminergic system with formaldehyde as the fixative. The rate and degree of fixation with formaldehyde was shown to be highly pH dependent. By perfusing the tissue with formaldehyde at pH 6.5 (where the rate of fixation is extremely slow) it is possible to rapidly distribute the fixative homogeneously into the tissue. By suddenly changing to a formaldehyde perfusate of higher pH, the cross-linking reaction is rapidly increased. This two-step fixation procedure provides a means of obtaining a rapid and uniform immobilization of the antigen, so that its translocation can be avoided. The final degree of fixation is controlled by the duration and pH of the second fixative solution. The results obtained by increasing the pH of the second solution demonstrated that complete fixation of tyrosine hydroxylase in the dopaminergic system with formaldehyde maybe obtained using a very basic formaldehyde solution (pH 11) while still retaining immunoreactivity of the enzyme. The localization that was achieved at lower pH appeared adequate until it was compared to the results obtained by perfusion at pH 11 in the second step.     

Pronase treatment increases the staining intensity of GABA-immunoreactive structures in the paravertebral sympathetic ganglia

A novel tissue preparation technique for improving gamma-aminobutyric acid (GABA) immunocytochemistry has been developed. The influence of the glutaraldehyde concentration in the fixative and the effect of pronase treatment on the GABA immunostaining were tested. This method includes fixation with a high concentration of glutaraldehyde, gelatin embedding and treatment of the sections with pronase. In sympathetic (paravertebral) ganglia and their connectives, the most intense and specific immunoreaction was obtained with the following procedure: immersion fixation in 5% glutaraldehyde, infiltration and embedding in 15% gelatin, secondary fixation of the samples with 4% formaldehyde, floating frozen sections and digestion with 0.1% pronase for 15-20 min. With this technique, the GABA-containing structures (cells and nerve fibers with varicosities forming basket-like networks around some principal neurons) were selectively labeled. The data presented suggest that (1) a high concentration (5%) of glutaraldehyde in the primary fixative is necessary to preserve a large proportion of the GABA content; (2) this glutaraldehyde fixation partly masks the GABA immunoreactivity; and (3) this masking may be overcome by a proteolytic treatment preceding the immunostaining. This method has been extensively tested for the light microscopic visualization of GABA-containing tissue components in the sympathetic ganglion chain, but it may probably also be used for the immunocytochemical detection of other small molecules in other parts of the nervous system.     

混合甲醛固定液固定大肠癌淋巴结标本的最佳免疫组化效果研究

目的:探讨混合甲醛固定液固定大肠癌淋巴结标本的最佳免疫组化效果。方法:采用不同pH值(6.0、7.0、8.0)的混合甲醛固定液对39枚大肠癌淋巴结标本进行不同时间(6 h、6 h-12 h、1 d-7 d)的固定处理。以细胞角蛋白20(CK20)为目标抗原,运用OIympusdp 70图像采集分析仪抽选出混合甲醛固定液最佳免疫组化染色的pH值及固定时间。结果:经pH值为7.0混合甲醛固定液处理后,阳性率为92.31%,高于经pH值为6.0、8.0的混合甲醛固定液处理后的76.92%、74.36%,且经pH值为7.0、8.0处理后的阳性率比较有统计差异(P0.05)。混合甲醛固定液的固定时间在6 h-12 h时的阳性率为94.87%,高于固定时间为6 h、1 d-7 d处理的30.77%、76.92%(P0.05)。结论:对于大肠癌淋巴结标本,以CK20为目标抗原,选择pH值为7.0的混合甲醛固定液固定6 h-12 h能够得到质量较佳的免疫组化染色效果。     

Localisation of EGF-Receptor mRNA in the nucleus of A431 cells by light microscopy.

We have localized the mRNA of the epidermal growth factor receptor (EGF-receptor) in nuclei of A431 cells by non-radioactive in situ hybridization at the light microscopical level using digoxigenin-labelled DNA probes. Both formaldehyde and glutaraldehyde fixations were tested before the hybridization was performed. Glutaraldehyde, compared with formaldehyde fixation, gives a less diffuse hybridization signal, which is easier to localize. Therefore, glutaraldehyde was used as a fixative in the hybridization experiments. It is demonstrated that the mRNA of the EGF-receptor is present in restricted domains mainly located around the nucleolus. This location of the EGF-receptor mRNA was unaltered after extraction of chromatin. Therefore it is concluded that the messenger RNA of the EGF-receptor is attached to the nuclear matrix. A possible biological role for the location of mRNA of the EGF-receptor around the nucleolus is discussed.     

A Temporal Threshold for Formaldehyde Crosslinking and Fixation

Background

Formaldehyde crosslinking is in widespread use as a biological fixative for microscopy and molecular biology. An assumption behind its use is that most biologically meaningful interactions are preserved by crosslinking, but the minimum length of time required for an interaction to become fixed has not been determined.

Methodology

Using a unique series of mutations in the DNA binding protein MeCP2, we show that in vivo interactions lasting less than 5 seconds are invisible in the microscope after formaldehyde fixation, though they are obvious in live cells. The stark contrast between live cell and fixed cell images illustrates hitherto unsuspected limitations to the fixation process. We show that chromatin immunoprecipitation, a technique in widespread use that depends on formaldehyde crosslinking, also fails to capture these transient interactions.

Conclusions/Significance

Our findings for the first time establish a minimum temporal limitation to crosslink chemistry that has implications for many fields of research.     

Safranin O reduces loss of glycosaminoglycans from bovine articular cartilage during histological specimen preparation

Summary The ability of Safranin O, added to fixation and decalcification solutions, to prevent the escape of glycosaminoglycans (GAGs) from small cartilage tissue blocks during histological processing of cartilage has been studied. GAGs in the fixatives and decalcifying solutions used and those remaining in the 1 mm³ cubes of cartilage were assayed biochemically. The quantity of GAGs remaining in the cartilage cubes were determined from Safranin O-stained sectins using videomicroscopy or microspectrophotometry. A quantity (10.6%) of GAGs were lost during a conventional 4% buffered formaldehyde fixation (48 h) and a subsequent decalcification in 10% EDTA (12 days) at 4°C. Rougly one-quarter of the total GAG loss occurred during the 48 h fixation, and three-quarters during the 12c days of decalcification. Inclusion of 4% formaldehyde in the decalcification fluid decreased the loss of GAGs to 6.2%. The presence of 0.5% Safranin O in the fixative reduced this loss to 3.4%. When 0.5% Safranin O was included in the fixative and 4% formaldehyde in the decalcification solution, Safranin O staining of the histological sections increased on average by 13.5%. After fixation in the presence of 0.5% Safranin O, there was no difference in the staining intensities when decalcification was carried out in the presence of either Safranin O or formaldehyde, or both. It took 24 h for Safranin O to penetrate into the deep zone of articular cartilage, warranting a fixation period of at least this long. In conclusion, the addition of Safranin O to the fixative and either Safranin O or formaldehyde in the following decalcification fluid, markedly reduces the loss of GAGs from small articular cartilage explants during histological processing. However, for immunohistochemical studies, Safranin O cannot be included in the processing solutions, because it may interfere.     

Pronase treatment increases the staining intensity of GABA-immunoreactive structures in the paravertebral sympathetic ganglia

Summary A novel tissue preparation technique for improving gamma-aminobutyric acid (GABA) immunocytochemistry has been developed. The influence of the glutaraldehyde concentration in the fixative and the effect of pronase treatment on the GABA immunostaining were tested. This method includes fixation with a high concentration of glutaraldehyde, gelatin embedding and treatment of the sections with pronase. In sympathetic (paravertebral) ganglia and their connectives, the most intense and specific immunoreaction was obtained with the following procedure: immersion fixation in 5% glutaraldehyde, infiltration and embedding in 15% gelatin, secondary fixation of the samples with 4% formaldehyde, floating frozen sections and digestion with 0.1% pronase for 15–20 min. With this technique, the GABA-containing structures (cells and nerve fibers with varicosities forming basket-like networks around some principal neurons) were selectively labeled. The data presented suggest that (1) a high concentration (5%) of glutaraldehyde in the primary fixative is necessary to preserve a large proportion of the GABA content; (2) this glutaraldehyde fixation partly masks the GABA immunoreactivity; and (3) this masking may be overcome by a proteolytic treatment preceding the immunostaining. This method has been extensively tested for the light microscopic visualization of GABA-containing tissue components in the sympathetic ganglion chain, but it may probably also be used for the immunocytochemical detection of other small molecules in other parts of the nervous system.     

Determination of the lowest concentrations of aldehyde fixatives for completely fixing various cellular structures by real-time imaging and quantification

The effectiveness of fixatives for fixing biological specimens has long been widely investigated. However, the lowest concentrations of fixatives needed to completely fix whole cells or various cellular structures remain unclear. Using real-time imaging and quantification, we determined the lowest concentrations of glutaraldehyde (0.001–0.005, ~0.005, 0.01–005, 0.01–005, and 0.01–0.1 %) and formaldehyde/paraformaldehyde (0.01–0.05, ~0.05, 0.5–1, 1–1.5, and 0.5–1 %) required to completely fix focal adhesions, cell-surface particles, stress fibers, the cell cortex, and the inner structures of human umbilical vein endothelial cells within 20 min. With prolonged fixation times (>20 min), the concentration of fixative required to completely fix these structures will shift to even lower values. These data may help us understand and optimize fixation protocols and understand the potential effects of the small quantities of endogenously generated aldehydes in human cells. We also determined the lowest concentration of glutaraldehyde (0.5 %) and formaldehyde/paraformaldehyde (2 %) required to induce cell blebbing. We found that the average number and size of the fixation-induced blebs per cell were dependent on both fixative concentration and cell spread area, but were independent of temperature. These data provide important information for understanding cell blebbing, and may help optimize the vesiculation-based technique used to isolate plasma membrane by suggesting ways of controlling the number or size of fixation-induced cell blebs.     

Localization of heparan sulfate proteoglycan in basement membrane by side chain staining with cuprolinic blue as compared with core protein labeling with immunogold.

We localized heparan sulfate proteoglycan (HSPG) in the basement membranes of ciliary epithelium and plantar epidermis, using Cuprolinic blue to stain its side chains and an immunogold procedure to detect its core protein. In accord with most of the literature, staining with Cuprolinic blue in glutaraldehyde fixative yielded three to five times as many reaction products along the two surfaces than along the center of the lamina densa, whereas immunogold labeling for the core protein after formaldehyde fixation yielded about twice as many gold particles over the center than along the surfaces of the lamina densa. It therefore appeared that HSPG side chains predominated outside, and the core protein within, the lamina densa. To find out whether the discrepancy was true or was an artifact caused by differences in processing, we attempted to combine the two approaches on the same material. This was found possible when Cuprolinic blue was used in formaldehyde fixative, embedding was in LR White, and immunogold labeling was performed on thin sections as usual. Under these conditions, both Cuprolinic blue reaction products and immunogold particles predominated over the lamina densa in the two basement membranes under study. Moreover, evidence was present that reaction products and immunogold particles either overlapped each other or were closely associated. The lens capsule (a thick basement membrane) also showed their co-localization. The discrepancy initially observed between side chains and core protein location was attributed to differences in processing, since Cuprolinic blue staining had been carried out in the course of glutaraldehyde fixation whereas immunogold labeling was done after formaldehyde fixation. The results lead to two conclusions. First, processing differences may alter the localization of HSPG and possibly other proteoglycans. Second, both HSPG side chains and core protein are localized in the same sites within basement membrane.     

Determination of optimal rehydration, fixation and staining methods for histological and immunohistochemical analysis of mummified soft tissues.

During an excavation headed by the German Institute for Archaeology, Cairo, at the tombs of the nobles in Thebes-West, Upper Egypt, three types of tissues from different mummies were sampled to compare 13 well known rehydration methods for mummified tissue with three newly developed methods. Furthermore, three fixatives were tested with each of the rehydration fluids. Meniscus (fibrocartilage), skin, and a placenta were used for this study. The rehydration and fixation procedures were uniform for all methods. The stains used were standard hematoxylin and eosin, elastica van Gieson, periodic acid-Schiff, and Grocott, and five commercially obtained immunohistochemical stains including pancytokeratin, vimentin, alpha-smooth-muscle-actin, basement membrane collagen type IV, and S-100 protein. The sections were examined by transmitted light microscopy. Our study showed that preservation of the tissue is dependent on the quality and effectiveness of the combination of the rehydration and fixation solutions, and that the quality of the histological and histochemical stains is dependent on the tissue quality. In addition, preservation of the antigens in the tissues is dependent on tissue quality, and fungal permeation had no influence on the tissue. Finally, the results are tissue specific. For placenta the best solution combination was Sandison and solution III (both fixed with formaldehyde) while results for skin were best with Ruffer I (using formaldehyde and Schaffer as fixatives), Grupe et al. (using formaldehyde as a fixative) and solution III (in combination with formaldehyde and Bouin fixatives). Ruffer II (using formaldehyde as a fixative) and solution III (in combination with Schaffer fixative) gave the best results for fibrocartilage.     

Effect of fixation on demonstration of phosphatases of Eimeria tenella grown in chick kidney cell cultures.

The effects of fixation with various concentrations of glutaraldehyde or formaldehyde, acetone or ethanol, and freeze-drying on 5 phosphatases of Eimeria tenella and chick kidney cell cultures were demonstrated in situ. Gultaraldehyde inactivated the phosphatases more than did the formaldehyde, but the effect of the combination of the 2 (Karnovsky's fixative) was greater than that of either glutaraldehyde or formaldehyde alone. The higher the concentration of aldehyde and the longer the duration of exposure, the greater the inactivation. The order of sensitivity to aldehyde fixation of the enzymes tested was glucose-6-phosphatase greater than thiamine pyrophosphatase greater than 5'-nucleotidase greater than adenosine triphosphatase greater than acid phosphatase. Cytologic detail was preserved more efficiently with glutaraldehyde than with formaldehyde. Optimal preservation of enzyme activity for cytochemistry was with 2% glutaraldehyde for 30 min or 2% formaldehyde for 1 hr for G-6-Pase, TPPase, and 5'-nucleotidase, and with 2% glutaraldehyde or 2% formaldehyde for 2 hr with ATPase and AcPase. Quenching with subsequent fixation in cold acetone or ethanol resulted in complete inactivation of G-6-Pase, TPPase, and 5'-nucleotidase; although cells fixed in this manner yielded large amounts of reaction product for ATPase and AcPase, the distribution was diffuse, and some of it appeared to be artifactual. Quenching with subsequent freeze-drying was unsatisfactory because nearly all of the cell layers rolled off the cover glasses.     

Impact of glutaraldehyde versus glutaraldehyde-formaldehyde fixative on cell organization in fish corneal epithelium

The purpose of this study was to examine the impact of a low osmolality glutaraldehyde fixative and a high osmolality glutaraldehyde-formaldehyde fixative on the structural organization of a tissue that could be exposed to low and high osmolality environments. The corneas of freshwater trout were prepared for transmission and scanning electron microscopy using either a fixative of 2% glutaraldehyde in 60 mM cacodylate buffer (pH 7.8, 260 mOsm/l) or a fixative prepared by adding 2.5% glutaraldehyde to a solution of 1% formaldehyde and buffering the solution with 0.1 M cacodylate (pH 7.6, 850 mOsm/l; Karnovsky-type fixative). The corneal epithelial cell layer thickness was greater after glutaraldehyde compared to glutaraldehyde-formaldehyde fixation (67 vs 55 mum), as was the thickness of the superficial cells (5.1 vs 3.4 mum) and basal cells (43 vs 38 mum). The intermediate (wing) cells of the epithelium were, however, less thick after glutaraldehyde fixation (15 vs 18 mum). The width of the squamous, intermediate and basal cells was greater following glutaraldehyde fixation with the effect being greatest in the superficial layers and insignificant at the level of the basal cells. The results show that chemical fixatives with extremes of osmolality cannot only produce different cell sizes in a tissue but also determine the overall organization of the cells in a positional-dependent fashion.     

Glycosyltransferases in plant and animal tissues effects of fixation and lead on enzyme activity.

As the initial step toward the cytochemical localization of glycosyl-transferases in situ, biochemical determinations of these enzyme activities from onion root tips and L1210 cells were performed before and after fixation as well as in the presence of lead ions. Glycosyltransferase activity from roots fixed in buffered formaldehyde or glutaraldehyde before homogenization decreased as the concentration of the fixative or fixation time was increased. Formaldehyde fixation was less inhibitory than glutaraldehyde; 35% of the glycosyltransferase activity was retained after 30 min fixation in 2% formaldehyde while 25% of the enzyme activity remained after a similar fixation in glutaraldehyde. Substantially higher levels of L1210 cell glycosyltransferase activity were retained after a 30 min 2% formaldehyde fixation (60% sialyltransferase; 82% galactosyltransferase), but inhibition by glutaraldehyde was similar to that observed for onion root galactosyltransferase. Glycosyltransferase from formaldehyde-fixed roots was inhbited 35% by lead nitrate, but sialytransferase from formaldehyde-fixed L1210 cells was unaffected by lead ions. These findings are encouraging for further studies aimed at the development of cytochemical technique to localize glycosyltransferase in plant and animal tissues.     

The importance of formaldehyde purity in studies on the electrokinetic charge of human red cells

Electrokinetic measurements and rheological studies conducted in parallel have previously shown red cell surface charge to play a role in governing aggregative behavior and bulk flow properties of red cell suspensions. For these and other types of model investigations, aldehyde stabilized cells have been widely used. In this communication, the influence of the purity of formaldehyde was investigated. It was found that (a) the direct dissolution of commercially available paraformaldehyde in water or suitably buffered saline results in impure solutions which, if utilized in the fixation of human erythrocytes, produces cells which have significantly different electrophoretic properties from native cells; (b) the basis for the differences is the presence of metallic impurities in some commercially available paraformaldehyde preparations; (c) the impurities and thus the anomalous electrokinetic properties of the fixed cells may be eliminated by generating formaldehyde gas from paraformaldehyde by heating the latter to 203-210 degrees C; (d) alternatively, the impurities may be eliminated by addition of disodium ethylenediamine tetraacetate dihydrate to fixative solutions prepared directly from paraformaldehyde.