Glyoxal fixation: how it works and why it only occasionally needs antigen retrieval

Over the past 13 years, glyoxal has become the leading alternative to formaldehyde as a histological fixative because of its low inhalation risk, faster reaction rate and selective control over crosslinking. The latter attribute is especially important, because most of the difficulties relating to use of formaldehyde-fixed specimens for immunohistochemistry stem from its aggressive crosslinking behavior. With suitable catalysts or other reaction accelerators, glyoxal forms 2-carbon adducts with nearly all end groups in proteins and carbohydrates, leaving most of them unimpaired for subsequent immunohistochemical demonstration. Only arginine is seriously impaired by the formation of imidazoles, which is the basis for the well known arginine blockade method using glyoxal. A special glyoxal-specific antigen retrieval method using high pH and high temperature effectively reverses the blockade and restores immunoreactivity. Other methods for antigen retrieval are rarely beneficial and in most cases damage the specimen. Special stains work well, except silver methods for Helicobacter pylori. Routine hematoxylin and eosin preparations exhibit clarity and cellular detail rarely seen with formaldehyde.     

New insights into protein crosslinking via the Maillard reaction: structural requirements,the effect on enzyme function,and predicted efficacy of crosslinking inhibitors as anti-ageing therapeutics

Protein crosslinking via the Maillard reaction with alpha-dicarbonyl compounds has been the subject of intense literature scrutiny. We report here a systematic study of three previously-neglected aspects of the reaction. Firstly, structural requirements were probed. An arginine-free peptide that contains two lysine residues, and a lysine-free peptide that contains arginine, were reacted with glyoxal, methylglyoxal and biacetyl. Methylglyoxal was able to crosslink in the absence of arginine residues, but glyoxal and biacetyl were not. Glyoxal crosslinked the lysine-free peptide via the N-terminus, but methylglyoxal and biacetyl could not. In this study, crosslinking did not require the presence of arginine but did require a free amino group, from a lysine residue, or the N-terminus. Thus specificity in structural requirements for protein crosslinking by alpha-dicarbonyls has been demonstrated. Secondly, protein function following glycation was examined by treating ribonuclease A with the three alpha-dicarbonyls, which were shown both to crosslink the enzyme and impair enzymatic activity. Thirdly, the effects of two reported Maillard reaction inhibitors, aminoguanidine and 3,5-dimethylpyrazole-1-carboxamidine on the crosslinking reaction were assessed, with a parallel measurement of the effect on enzyme activity. The results demonstrate that preventing protein crosslinking does not necessarily preserve enzyme activity. These results cast doubt on the likely efficacy of some purported anti-ageing compounds in vivo.     

Histomorphometric comparison after fixation with formaldehyde or glyoxal

Abstract

Formaldehyde has long been the fixative of choice for histological examination of tissue. The use of alternatives to formaldehyde has grown, however, owing to the serious hazards associated with its use. Companies have striven to maintain the morphological characteristics of formaldehyde-fixed tissue when developing alternatives. Glyoxal-based fixatives now are among the most popular formaldehyde alternatives. Although there are many studies that compare staining quality and immunoreactivity, there have been no studies that quantify possible structural differences. Histomorphometric analysis commonly is used to evaluate diseased tissue. We compared fixation with formaldehyde and glyoxal with regard to the histomorphological properties of plantar foot tissue using a combination of stereological methods and quantitative morphology. We measured skin thickness, interdigitation index, elastic septa thickness, and adipocyte area and diameter. No significant differences were observed between formaldehyde and glyoxal fixation for any feature measured. The glyoxal-based fixative used therefore is a suitable fixative for structural evaluation of plantar soft tissue. Measurements obtained from the glyoxal-fixed tissue can be combined with data obtained from formalin-fixed for analysis.     

Immunohistochemical detection of p53 protein in basal cell skin cancer after microwave-assisted antigen retrieval

p53 is the most frequently altered tumor-suppressor gene in skin cancer. In normal tissues the p53 protein (wild type) has a very short half-life and it is not detectable immunohistochemically. In contrast, the mutant p53 protein has an extended half-life in tumor cells and can be detected by immunohistochemical methods. p53 is widely used as an indicator of tumor aggression and progression. Fixation methods especially formaldehyde based fixation may mask the immunohistochemical detection of p53 protein but antigen retrieval methods enhance the inmmunohistochemical detection of p53 protein by remodification of protein structure. This study was designed to evaluate the efficacy of different fixatives, of microwaving and microwave pretreatment method to retrieve p53 immunoreactivity in paraffin-embedded non-lesioned (adjacent normal tissue) human skin samples or pathological human skin samples diagnosed as basal cell carcinoma. The samples were fixed at RT and/or in microwave oven either in neutral buffered formalin or alcohol for different time periods. For antigen retrieval, the sections were irradiated in a microwave oven for 5 cycles in 10 mM citrate buffer (pH 6.00). In this study the effects of six different fixation methods on the immunohistochemical staining have been investigated in basal cell tumor specimens. The application of antigen retrieval method was also examined and compared. Optimal results were obtained using samples fixed in alcohol either at room temperature (24 h) or in microwave oven.     

Blockade of the antigen-antibody reaction using benzil condensation with the guanidyl residue of arginine

Summary Benzil blockade of the guanidyl group of arginine was tried on sections of paraffin-embedded tissue fixed in two different fixatives, in an attempt to evaluate the relevance of this amino acid to the reaction of several proteins with their corresponding antibodies. The two fixatives were 10% formaldehyde, and Bouin's fluid without acetic acid. Both polyclonal and monoclonal antibodies against proteins or peptides (lysozyme, adrenocorticotropic hormone, growth hormone, placental lactogen, and prolactin) were used on human biopsies or material from autopsies. The blockade was effective when monoclonal antibodies were used, whereas no effect or only a small decrease of the intensity of the reaction was observed with polyclonal antibodies. The least definitive result was obtained with prolactin, where a complete blockade was never achieved with monoclonal antibodies. Calcitonin, a peptide that does not contain arginine, was used as a control not susceptible to benzil blockade; no blockade of immunostaining was observed.     

The prebiotic synthesis and catalytic role of imidazoles and other condensing agents

In the past decade significant advances have been made in the synthesis of oligonucleotides and other polymers by means of imidazoles and other condensing agents. In spite of the current knowledge of the chemistry of imidazoles and their importance as prebiotic catalysts, their formation under primitive earth conditions has not been properly demonstrated. We have now been able to synthesize imidazole as well as its 2-methyl and 4-methyl derivatives under plausible prebiotic conditions. One method utilizes an aldehyde (formaldehyde or acetaldehyde), glyoxal and ammonia as the starting materials for the formation of imidazole and 2-methylimidazole. The other method uses a carbohydrate and ammonia as the key reagents for the synthesis of 4-methylimidazole. The importance of imidazole and related compounds (e.g., cyanamide) in the synthesis of oligonucleotides has been studied by us as well as others. Apparently the charge relay group (–N–C–N–) present in imidazoles, carbodiimides, cyanamide, or the histidine and arginine of enzyme active centers is essential for the synthesis of phosphodiester and pyrophosphate bonds.     

The prebiotic synthesis and catalytic role of imidazoles and other condensing agents

In the past decade significant advances have been made in the synthesis of oligonucleotides and other polymers by means of imidazoles and other condensing agents. In spite of the current knowledge of the chemistry of imidazoles and their importance as prebiotic catalysts, their formation under primitive earth conditions has not been properly demonstrated. We have now been able to synthesize imidazole as well as its 2-methyl and 4-methyl derivatives under plausible prebiotic conditions. One method utilizes an aldehyde (formaldehyde or acetaldehyde), glyoxal and ammonia as the starting materials for the formation of imidazole and 2-methylimidazole. The other method uses a carbohydrate and ammonia as the key reagents for the synthesis of 4-methylimidazole. The importance of imidazole and related compounds (e.g., cyanamide) in the synthesis of oligonucleotides has been studied by us as well as others. Apparently the charge relay group (-N-C-N-) present in imidazoles, carbodiimides, cyanamide, or the histidine and arginine of enzyme active centers is essential for the synthesis of phosphodiester and pyrophosphate bonds.     

Protein fixation and antigen retrieval: chemical studies

Abstract

Fixation with formaldehyde is the first process to which most biopsy and necropsy specimens are exposed prior to dehydration and embedding in paraffin wax. Tissue specimens that have been fixed in formaldehyde have architectural characteristics that are familiar to virtually every pathologist and these facilitate routine diagnosis. Nevertheless, formaldehyde fixation has some deleterious effects including reduction in immunoreactivity and degradation of nucleic acids. Development of methods to counteract these deleterious effects requires an understanding of the chemical events that occur during tissue fixation and subsequent tissue processing. This short review illustrates some of the chemical consequences of formaldehyde fixation and ethanol dehydration. It also provides some insight into the molecular events accompanying heat-induced antigen retrieval.     

The reactions of phenylglyoxal and related reagents with amino acids.

1. The reaction of phenylglyoxal (PGO), glyoxal (GO), and methylglyoxal (MGO) with amino acids were investigated at mild pH values at 25 degrees. These aldehydes reacted most rapidly with arginine and the rate of reaction increased with increasing pH values. Histidine, cystine, glycine, tryptophan, asparagine, glutamine, and lysine reacted with these aldehydes at significant but various rates, depending on the pH and the kind of the reagent used. The reactions with these amino acids seemed to involve both the alpha-amino groups and the side chain groups, and no significant reaction appeared to occur with the side chain alone except with those of arginine, lysine, and cysteine. These reagents were similarly reactive with the guanidinium group of arginine, but PGO appeared to be much less reactive with the epsilone-amino group of lysine than MGO and GO. The other ordinary amino acids were very much less reactive or did not react at all with these reagents, with the exception of cysteine. 2. Di-PGO-L-arginine was prepared from Nalpha-benzyloxycarbonyl-L-arginine, and di-PGO-methylguanidine from methylguanidine, and the stoichiometry of the reaction of two PGO molecules with one guanidino group was confirmed. A glyoxal derivative of L-arginine (GO-arginine) was prepared by reaction of glyoxal with arginine. GO-arginine was fairly unstable, especially at higher pH values. A similar derivative (MGO-arginine) was also found to be formed by reaction of MGO with L-arginine, and was similarly unstable. These derivatives, however, did not regenerate arginine upon acid hydrolysis.     

The reactions between formaldehyde,glutaraldehyde and osmium tetroxide,and their fixation effects on bovine serum albumin and on tissue blocks

Summary The reactions between osmium tetroxide and glutaraldehyde and formaldehyde were investigated. It was found that they react together to form intermediate products which then break down to form osmium black. Glutaraldehyde reacts much more rapidly with osmium tetroxide than formaldehyde. The rates of the reactions are increased by increasing the glutaraldehyde concentration or adding bovine serum albumin to the reaction mixture. The reaction rates increase with temperature. The mixtures of fixatives were also tried on tissues and the results paralleled the model experiments. The crosslinking of bovine serum albumin by osmium tetroxide, formaldehyde and glutaraldehyde singly and in mixtures was quantitatively assessed by viscosimetry, gel filtration and disc electrophoresis coupled with densitometry. The crosslinking of bovine serum albumin by pairs of fixatives was less than that produced by the most effective of the pair. After 5 min reaction osmium tetroxide was the most effective crosslinking agent according to viscosimetric experiments, but after one hour's reaction with bovine serum albumin, glutaraldehyde was revealed as the most effective crosslinking agent by gel filtration and electrophoresis.     

The Sugar Model: Catalysis by Amines and Amino Acid Products

Ammonia and amines (including amino acids) were shown tocatalyze the formation of sugars from formaldehyde andglycolaldehyde, and the subsequent conversion of sugars tocarbonyl-containing products under the conditions studied (pH5.5 and 50°C). Sterically unhindered primary amineswere better catalysts than ammonia, secondary amines, andsterically hindered primary amines (i.e.-aminoisobutyric acid). Reactions catalyzed by primaryamines initially consumed formaldehyde and glycolaldehyde about15–20 times faster than an uncatalyzed control reaction. Theamine-catalyzed reactions yielded aldotriose (glyceraldehyde),ketotriose (dihydroxyacetone), aldotetroses (erythrose andthreose), ketotetrose (erythrulose), pyruvaldehyde, acetaldehyde,glyoxal, pyruvate, glyoxylate, and several unindentifiedcarbonyl products. The concentrations of the carbonyl products,except pyruvate and ketotetrose, initially increased and thendeclined during the reaction, indicating their ultimateconversion to other products (like larger sugars or pyruvate).The uncatalyzed control reaction yielded no pyruvate orglyoxylate, and only trace amounts of pyruvaldehyde, acetaldehyde and glyoxal. In the presence of 15 mM catalyticprimary amine, such as alanine, the rates of triose andpyruvaldehyde of synthesis were about 15-times and 1200-timesfaster, respectively, than the uncatalyzed reaction. Sinceprevious studies established that alanine is synthesized fromglycolaldehyde and formaldehyde via pyruvaldehyde as its directprecursor, the demonstration that the alanine catalyzes theconversion of glycolaldehyde and formaldehyde to pyruvaldehydeindicates that this synthetic pathway is capable ofautocatalysis. The relevance of this synthetic process, namedthe Sugar Model, to the origin of life is discussed.     

Further studies on the reactions of phenylglyoxal and related reagents with proteins.

1. The reactivities of phenylglyoxal (PGO), glyoxal (GO), and/or methylglyoxal (MGO) with several proteins, including ribonuclease A [EC 3.1.4.22] and its derivatives, alpha-chymotrypsin [EC 3.4.21.1], trypsin [EC 3.4.21.4], lysozyme [EC 3.2.1.17], pepsin [EC 3.4.23.1], rennin [EC 3.4.23.4], thermolysin, and insulin and its B chain, have been examined. From analyses of the reaction products, PGO was shown to be the most specific for arginine residues. GO and MGO also reacted rapidly with arginine residues, but they also reacted with lysine residues to a significant extent. A side reaction with N-terminal alpha-amino groups was observed with each of these reagents. 2. Two arginine residues out of four in ribonuclease A, two out of three in alpha-chymotrypsin, one out of two in trypsin, one out of two in pepsin, and one out of five in rennin appeared to react with PGO fairly rapidly, indicating a difference in the relative accessibility of these residues by the reagent. Extensive modification of the arginine residues by PGO occurred with RCM-derivatives of ribonuclease A and insulin B chain. The N-terminal isoleucine residues of alpha-chymotrypsin and trypsin appeared to be unreactive with PGO because of salt bridge formation with an aspartyl residue. The activity of alpha-chymotrypsin toward N-benzoyl-L-tyrosine ethyl ester and the lytic activity of lysozyme were lost rapidly on treatment with PGO, as in the case of ribonuclease A. Pepsin and rennin were only partially inactivated by reaction with PGO.     

Immobilization of microbial cells in crosslinked,prepolymerized, linear polyacrylamide gels: Antibiotic production by immobilized Streptomyces clavuligerus cells

A mild new method for the immobilization whole microbial cells has been developed. Cells were suspended in a solution of preformed, linear, water-soluble Polyacrylamide chains, partially substituted with acylhydrazide groups. The Prepolymerized backbone polymer was crosslinked, in the presence of viable cells, by stoichiometric amounts of dialdehydes such as glyoxal, glutardialdehyde, and period ate-oxidized polyvinyl alcohol. The crosslinking reaction, carried out in cold, neutral physiological conditions resulted in cells entrapped in gels with physical properties similar to those of the common Polyacrylamide gels. However, cell damage generally caused by the acrylamide monomer was avoided. Resting Streptomyces clavuligerus cells, possessing a high capacity for antibiotic production, were entrapped according to this procedure. These immobilized cells produced cephalosporins continuously for 96 h with yields similar to those of free resting cells. The same cells, when immobilized by direct polymerization acrylamide monomers, yielded significantly lower amount of antibiotics.     

The enhanced reactivity of endogenous biotin-like molecules by antigen retrieval procedures and signal amplification with tyramine

In diagnostic pathology and immunocytochemical research, immunohistochemical techniques using the streptavidin–biotin–peroxidase system have played an extremely valuable role. This system, based on the high affinity of streptavidin for biotin, may, however, provoke false positive results because of endogenous streptavidin-binding sites in human tissues. With the advent of the antigen retrieval procedure and signal amplification method, this problem can be serious enough to cause mistakes in interpreting immunohistochemical staining results. Therefore, we examined the distribution of endogenous biotin-like molecules in various human tissues and the influence of various antigen retrieval procedures with or without signal amplification using biotinylated tyramine to reveal these biotin-like activities. We observed that endogenous biotin-like molecules were present in a wide range of tissues, and their activity was markedly enhanced by employing antigen retrieval procedures or signal amplification. Furthermore, the extent to which the activity of endogenous biotin-like activities was enhanced depended on the kinds of antigen retrieval procedures and signal amplification employed. Pressure cooking and tyramine amplification with microwave heating showed the highest activities. These results show that the antigen retrieval procedures and signal amplification with tyramine can enhance the activity of endogenous biotin or biotin-like molecules as well as antigenicity, which can be a pitfall in the interpretation of immunohistochemical data.     

系统解剖学立体化双语教学资源建设的探讨

系统解剖学是医学生最为重要的专业基础课程之一。近年来,我们一直坚持双语教学,2008年我校系统解剖学获得首批国家双语教学示范课程。为建设好双语教学示范课程,我们积极开展解剖学双语教学探索和实践,着重于该门课程的立体化双语教学资源的建设,以纸质教材为主体,利用不同教学媒体的优点来呈现解剖学不同的教学内容,形成一个立体化的双语教学资源,并应用于教学实践活动中,达到提高学生专业英语理解能力,灵活运用外语思维解决医学问题能力的目标。     

Energy filtering transmission electron microscopy immunocytochemistry and antigen retrieval of surface layer proteins from Tannerella forsythensis using microwave or autoclave heating with citraconic anhydride

Tannerella forsythensis (Bacteroides forsythus), an anaerobic Gram-negative species of bacteria that plays a role in the progression of periodontal disease, has a unique bacterial protein profile. It is characterized by two unique protein bands with molecular weights of more than 200 kDa. It also is known to have a typical surface layer (S-layer) consisting of regularly arrayed subunits outside the outer membrane. We examined the relationship between high molecular weight proteins and the S-layer using electron microscopic immunolabeling with chemical fixation and an antigen retrieval procedure consisting of heating in a microwave oven or autoclave with citraconic anhydride. Immunogold particles were localized clearly at the outermost cell surface. We also used energy-filtering transmission electron microscopy (EFTEM) to visualize 3, 3′-diaminobenzidine tetrahydrochloride (DAB) reaction products after microwave antigen retrieval with 1% citraconic anhydride. The three-window method for electron spectroscopic images (ESI) of nitrogen by the EFTEM reflected the presence of moieties demonstrated by the DAB reaction with horseradish peroxidase (HRP)-conjugated secondary antibodies instead of immunogold particles. The mapping patterns of net nitrogen were restricted to the outermost cell surface.     

一种改良的BrdU免疫组织化学染色抗原热修复技术

目的：探索一种简单有效的行BrdU免疫组织化学染色抗原热修复的方法。方法：本实验探索了三种抗原热修复方法：1）漂片煮沸法,2）贴片煮沸法,3）贴片改良法。将贴有冰冻组织切片的玻片置于恒温封闭体系中进行热修复。之后行BrdU免疫组化染色,栗集图像对这三种热修复方法进行比较。针对贴片改良法行BrdU与NeuN、P。CERB和DCX的荧光双标,采集图像以观察该方法在免疫荧光甄标实验中应用的可行性。结果：1）漂片煮沸法脑组织切片在经过热修复处理后,切片卷起皱缩,不能进行后续实验步骤;2）贴片煮沸法可见少量BrdU阳性细胞,但背景深,且少数脑片起泡,假阳性现象严重;3）贴片改良法B-U免疫组化及与NeuN、P-CERB和DCX的免疫荧光双标染色背景浅,阳性细胞明显。结论：采用改良的热修复法能充分暴露BrdU抗原,DAB显色及免疫荧光染色结果理想。此方法为一种较好的行BrdU免疫组织化学染色抗原热修复方法。