Immunohistochemical analyses on albumin and immunoglobulin in acute hypertensive mouse kidneys by "in vivo cryotechnique"

The purpose of this study is to visualize topographical changes of serum proteins, albumin and immunoglobulin, passing through mouse glomerular capillary loops and their reabsorption in renal proximal tubules by immunohistochemistry in combination with our "in vivo cryotechnique". The "in vivo cryotechnique" was performed on left mouse kidneys under normotensive, experimentally acute hypertensive and heart-arrest conditions. The cryofixed tissues by the technique were routinely processed for freeze-substitution. Serial deparaffinized sections were stained with hematoxylin-eosine and immunostained with anti-mouse albumin, immunoglobulin G (IgG), kappa or lambda light chain and IgG1 heavy chain antibodies. Under the normotensive and heart-arrest conditions, albumin and IgG were clearly immunolocalized in blood vessels and slightly in apical cytoplasmic parts of some proximal tubules. Under the acute hypertensive condition, the albumin and kappa or lambda light chains, but not IgG1 heavy chain, were strongly immunolocalized in the apical cytoplasm of almost all proximal tubules. This study is the first in vivo visualization for glomerular passage of serum proteins and their transtubular absorption. Thus, the "in vivo cryotechnique" with freeze-substitution can be used for clarifying not only the functional morphology of living animal cells, but also in situ immunohistochemical localization of their components.     

Immunohistochemical study of serum albumin in normal and cadmium-treated mouse testis organs by "in vivo cryotechnique"

The in vivo injection of cadmium (Cd) was reported to induce blood-testis barrier disruption, and assumed to be an experimental model to examine junctional structures in seminiferous tubules. The purpose of this study is to investigate time-dependent changes of albumin permeability in the normal or Cd-treated mouse testis by our "in vivo cryotechnique" with immunohistochemistry, reflecting tight junctional (TJ) barriers of Sertoli cells. The albumin in the seminiferous tubules was firstly immobilized by the cryotechnique, in which normal blood circulation was always kept. The cryofixed testicular tissues were then processed for freeze-substitution, and embedded in the paraffin wax. Serial sections were immunostained by anti-mouse albumin antibody with peroxidase immunostaining, and also stained with hematoxylin-eosine (HE) for morphological observation. In normal seminiferous tubules, the immunoreaction products were localized around peritubular myoid cells and between Leydig cells, as well as in blood vessels. They were also localized as arch-like patterns around some spermatogonia in basal compartments of seminiferous tubules. Twenty-four and 48 hrs after Cd-treatment, some enlarged spaces and vesicular formations in the seminiferous epithelium were observed on the HE-stained sections. The albumin immunolocalization was detected not only in the basal compartments, but also in the adluminal compartments between Sertoli cells and germ cells. Thus, the structural disruptions of inter-Sertoli TJ barriers could be clearly demonstrated by the "in vivo cryotechnique".     

Immunohistochemical detection of phosphorylated rhodopsin in light-exposed retina of living mouse with in vivo cryotechnique.

The purpose of this study is to analyze the time-dependent molecular states of rhodopsin (Rho) phosphorylation in the specimens originating from eyeballs cryoimmobilized in situ in living animals. Whole eyeballs of living mice under various dark- and light-exposure conditions were quickly frozen using the in vivo cryotechnique with isopentane-propane cryogen cooled down in liquid nitrogen (-196C). The frozen whole-mount eyeballs were freeze substituted in acetone containing paraformaldehyde and embedded in paraffin wax. Deparaffinized sections were immunostained with anti-phosphorylated (334)Ser Rho (P-Rho334) antibody. Immunoreactivity of P-Rho334 was specifically recognized in the outer segments of mouse retinas exposed to daylight. In the 12-h dark-adapted retinas, P-Rho334 immunoreactivity was completely eliminated. Moreover, in other retinas dark adapted for 12 or 36 hr and then exposed under the safety red light for 2 min, it was still barely recognized. Even in the eyeballs exposed to strong visible light for 10 sec, it was not detected. However, after 30, 60, and 180 sec of visible light exposure, P-Rho334 immunoreactivity was definitely recovered, similar to that under daylight condition. This is a new immunohistochemical approach to visualize the time-dependent Rho phosphorylation of living mice using the in vivo cryotechnique, in which changes could be detected within seconds following exposure to light.     

Detection of MAPK signal transduction proteins in an ischemia/reperfusion model of mouse intestine using in vivo cryotechnique

Intestinal ischemia and ischemia–reperfusion rapidly progress to tissue destruction and reconstruction of functional organs. To date, precise immunolocalizations and the timing of appearance of cell signaling components under such conditions have not been well visualized. Mitogen-activated protein kinase (MAPK) signal transduction pathways have been reported to be activated under various types of cell damage, and cyclic AMP response element-binding protein (CREB) was directly phosphorylated with various cellular stimuli. In this study, both the expression and the immunolocalization of ERK1/2, a member of the MAPK family, were examined in mouse intestinal tissues by in vivo cryotechnique, which is useful to retain soluble molecules including cell signaling molecules. Under normal conditions, although ERK was widely immunolocalized in the cytoplasm of epithelial cells, phosphorylated (p) ERK1/2 was slightly detected in a small amount of epithelial cells in crypt and top parts of the villi. In 5 min ischemia, more pERK1/2 immunolocalization was detected in epithelial cells of the crypt part. Up to 60 min, the pERK1/2 immunoreactivity was remarkably increased in wide areas of epithelial cells. In the 20 and 60 min ischemia groups, phosphorylated CREB was also immunostained in the nuclei of the same epithelial cell areas of pERK1/2. In 20 min ischemia with 60 min reperfusion experiments, pERK1/2 immunointensity was reduced in the crypt areas. In 60 min ischemia with 60 min reperfusion, however, it was still strongly immunolocalized in epithelial cells of the crypts. Thus, rapidly changing ERK1/2 phosphorylation was visualized in the intestinal epithelial stem cells of mouse small intestine.     

Recent development of in vivo cryotechnique to cryobiopsy for living animals

Various microscopic methods have been used to analyze the morphology and molecular distribution of cells and tissues. Using conventional procedures, however, ischemic or anoxic artifacts are inevitably caused by tissue-resection or perfusion-fixation. The in vivo cryotechnique (IVCT) was developed to overcome these problems, and was found to be useful with light microscopy for analyses of the distribution of water-soluble molecules without anoxic effects at high time resolution. But there are limitations to the application of IVCT, such as exposure of target organs of living small animals and immunoreactivity of lipid-soluble molecules owing to freeze-substitution with acetone. Recently, a new cryotechnique called "cryobiopsy" has been developed, which enables one to obtain tissue specimens of large animals including humans without ischemia or anoxia, and has almost the same technical advantages as IVCT. Both IVCT and cryobiopsy complement other live-imaging techniques, and are useful for not only the morphological observation of cells and tissues under normal conditions, but also the preservation of all components in frozen tissue specimens. Therefore, morphofunctional information in vivo would be obtained by freeze-substituion for light or electron microscopy, and also by other analytical methods, such as freeze-fracture replication, X-ray microanalyses, or Raman microscopy. Considering the merits of both IVCT and cryobiopsy, their application should be expanded into other microscopic fields and also from experimental animal studies to clinical medicine.     

Application of "in vivo cryotechnique" to detect erythrocyte oxygen saturation in frozen mouse tissues with confocal Raman cryomicroscopy

To measure oxygen saturation (SO₂) of flowing erythrocytes in blood vessels of living animals, our “in vivo cryotechnique” (IVCT) was combined with confocal Raman microscopy at low temperature (−150 °C), referred to as cryomicroscopy. We evaluated two resonance Raman (RR) shifts around 1355 and 1378 cm⁻¹, reflecting de-oxygenated and oxygenated hemoglobin molecular structures, respectively. Judging from the calibration analyses of quickly frozen human whole blood for the control experiment in vitro, the two RR shifts were well retained at the low temperature, and their calculated ratios mostly reflected the relative SO₂ measured with a blood-gas analyzer. In blood vessels of living mouse organs prepared with the IVCT, their RR spectral peaks were also detected at the same RR shifts obtained in human blood. In the blood vessels of living mouse small intestines, some arterioles and venules were clearly distinguishable by monitoring different peak patterns of their RR shifts. The different ratios of the RR shift-areas were calculated even in the arterial vessels. In blood vessels of mouse livers, the Raman spectra showed a lower peak shift of 1378 cm⁻¹ compared to that of 1355 cm⁻¹, indicating an SO₂ decrease in hepatic blood circulation. Thus, the new cryopreparation technique will enable us to directly analyze the in vivo SO₂ in various tissues of a whole animal body prepared with the IVCT, reflecting their living states.     

Morphological study of erythrocyte shapes in red pulp of mouse spleens revealed by an in vivo cryotechnique

The purpose of this study was to clarify erythrocyte shapes in splenic cords of living mouse spleens, using our in vivo cryotechnique followed by scanning (SEM) or transmission (TEM) electron microscopy. Some spleens of mice were quickly frozen by the in vivo cryotechnique while their hearts were beating under anesthesia. In contrast, other spleens were prepared by an in vitro freezing method after they were taken out from the abdominal cavity. They were routinely freeze-substituted, and prepared for SEM and TEM. A few mouse spleens were also routinely fixed and embedded in Quetol-812 to obtain conventional morphology. Erythrocytes in living mouse spleens showed a variety of shapes with narrow spaces between them, trapped among reticular fiber tissues. Similar various shapes of erythrocytes were kept in the red pulp even after blocking normal blood circulation, as prepared by the in vitro freezing method. In comparison to the above-mentioned findings, some erythrocytes were changed to biconcave discoid shapes by the conventional immersion fixation with chemical fixatives. They also showed wide spaces between each other among reticular fiber tissues. Such conventional morphological studies could hardly reveal the in vivo shapes of erythrocytes in functioning spleens with normal blood circulation. In contrast, the various shapes of erythrocytes in the functioning spleens were demonstrated by our in vivo cryotechnique. It is suggested that most erythrocytes congesting in spleens keep their original configuration in spite of microenviromental alteration in splenic blood circulation.     

Acute kidney injury induced by protein-overload nephropathy down-regulates gene expression of hepatic cerebroside sulfotransferase in mice, resulting in reduction of liver and serum sulfatides

Sulfatides, possible antithrombotic factors belonging to sphingoglycolipids, are widely distributed in mammalian tissues and serum. We recently found that the level of serum sulfatides was significantly lower in hemodialysis patients than that in normal subjects, and that the serum level closely correlated to the incidence of cardiovascular disease. These findings suggest a relationship between the level of serum sulfatides and kidney function; however, the molecular mechanism underlying this relationship remains unclear. In the present study, the influence of kidney dysfunction on the metabolism of sulfatides was examined using an established murine model of acute kidney injury, protein-overload nephropathy in mice. Protein-overload treatment caused severe proximal tubular injuries within 4 days, and this treatment obviously decreased both serum and hepatic sulfatide levels. The sphingoid composition of serum sulfatides was very similar to that of hepatic ones at each time point, suggesting that the serum sulfatide level is dependent on the hepatic secretory ability of sulfatides. The treatment also decreased hepatic expression of cerebroside sulfotransferase (CST), a key enzyme in sulfatide metabolism, while it scarcely influenced the expression of the other sulfatide-metabolizing enzymes, including arylsulfatase A, ceramide galactosyltransferase, and galactosylceramidase. Pro-inflammatory responses were not detected in the liver of these mice; however, potential oxidative stress was increased. These results suggest that down-regulation of hepatic CST expression, probably affected by oxidative stress from kidney injury, causes reduction in liver and serum sulfatide levels. This novel mechanism, indicating the crosstalk between kidney injury and specific liver function, may prove useful for helping to understand the situation where human hemodialysis patients have low levels of serum sulfatides.     

Immunohistochemical analyses of cell cycle-related proteins, apoptosis, and proliferation in pituitary adenomas.

To analyze the cell cycle regulatory mechanisms in the growth of pituitary adenomas, we investigated immunohistochemically the expression of the cell cycle-related proteins cyclin A and p27 in 48 pituitary adenomas. The frequency of apoptosis and the proliferative potential were also examined. The percentage of apoptotic cells was evaluated by immunohistochemical analysis using the anti-single-strand DNA antibody. The proliferative potential was assessed using the anti-Ki-67 antibody. The mean cyclin A labeling index (LI) for the non-recurrent group was 1.03% and for the recurrent group 2.31%. A positive linear correlation between cyclin A LI and Ki-67 LI was found. The mean p27 LI for the non-recurrent group was 67.4% and for the recurrent group 47.0%. There were significant differences in cyclin A LI and p27 LI between the non-recurrent group and the recurrent group. The mean apoptotic rate for the non-recurrent group was 0.87% and for the recurrent group 1.05%. There was no significant difference. Multivariate regression analysis revealed that high cyclin A LI and high Ki-67 LI were significant factors for shorter progression-free survival. The results suggest that the cyclin A LI is a useful prognostic factor in pituitary adenomas. (J Histochem Cytochem 49:1193-1194, 2001)     

Immunohistochemical modifications of "B cells" in experimentally-induced pancreatic cancer--correlation with serum insulin values

In pancreatic ductal adenocarcinoma induced in the Syrian hamster by N-nitrosobis (2-oxopropyl) amine (Bop) B cells persisted with focal dispersion in the tumor zone. The localization of these varied depending on whether the animals had initial or long standing tumors. In the animals with initial tumors, immunohistochemical techniques indicated the B cells formed part of the tumoral glands and/or were intimately related to the cells of the walls of the tumor glands or present in the stroma. Insulin values were high in these animals. In the longer-developed tumors, insulin levels tended to be lower and although B cells were seen forming part of the tumor glands, those in the tumoral stroma were predominant.     

Quantification of interactions between drug leads and serum proteins by use of "binding efficiency"

To develop efficient and reliable methods for prediction of serum protein binding of drug leads, the kinetic characteristics for the interactions between selected compounds and human serum albumin and α₁-acid glycoprotein have been explored using a surface plasmon resonance biosensor. Conventional methods for quantification of interactions (i.e., using rate constants or affinities determined on the basis of a reasonable mechanistic model) were applicable for only a few of the compounds. The affinity of a primary interaction and the contribution of lower affinity secondary interactions could be estimated for some compounds, but the affinity of many compounds could not be quantified by either of these methods. To have a quantification method that could be used for all compounds, independent of affinity and complexity of interaction mechanisms, the concept of “binding efficiency,” analogous to “catalytic efficiency” used for enzymes, was developed. It allowed the quantification of the binding of compounds interacting with weak affinity and for which saturation is not reached within a concentration range where the compound is soluble or when the influence of interactions with secondary sites makes interpretations difficult. In addition, compounds with large fractional binding can be identified by this strategy and simply quantified relative to reference compounds. This approach will enable ranking and identification of structure–activity relationships of compounds with respect to their serum protein binding profile.     

Immunohistochemical detection of proliferating cells in vivo

Incorporation of the thymidine analogue 5-bromo-2'-deoxyuridine (BrUdR) into newly synthesized DNA provides the basis of a simple technique for identifying proliferating cells. BrUdR was administered to C57BL/6 mice by continuous infusion for 1-7 days, or by intraperitoneal injection for shorter intervals. Various tissue types, including gut, kidney, and liver, were excised, fixed in neutral buffered formalin, and paraffin-embedded for sectioning. De-paraffinized 4-micron tissue sections and bone marrow samples were incubated with an anti-BrUdR antibody and cells that had traversed S-phase during the BrUdR exposure period were identified immunohistochemically. Proliferation and migration of intestinal epithelial cells were identified by antibody staining after continuous in vivo exposure to BrUdR for 1-4 days, and BrUdR incorporation into proliferating marrow cells was detected within 30 min. Tissues such as normal liver, known to have low levels of proliferation, remained unstained after 3 days' exposure to BrUdR. After we established that normal proliferating cells could be identified using this technique, BrUdR was administered to mice bearing B16 melanomas. Again, proliferating tumor cells were clearly identified in histological sections. The nuclei from these paraffin-embedded tumors were also collected for flow cytometric analysis after de-waxing, rehydration, and pepsin treatment. This combination of techniques made possible the comparison in adjacent tissue sections of labeling index, obtained from stained sections, with percentage S-phase, measured using DNA flow cytometry. The % S-phase was consistently higher than the labeling index obtained with immunocytochemistry, and two-parameter DNA vs BrUdR flow cytometry showed that this difference could be accounted for by a population of unlabeled cells with an S-phase DNA content.     

Extensive in vivo metabolite-protein interactions revealed by large-scale systematic analyses

Natural small compounds comprise most cellular molecules and bind proteins as substrates, products, cofactors, and ligands. However, a large-scale investigation of in?vivo protein-small metabolite interactions has not been performed. We developed a mass spectrometry assay for the large-scale identification of in?vivo protein-hydrophobic small metabolite interactions in yeast and analyzed compounds that bind ergosterol biosynthetic proteins and protein kinases. Many of these proteins bind small metabolites; a few interactions were previously known, but the vast majority are new. Importantly, many key regulatory proteins such as protein kinases bind metabolites. Ergosterol was found to bind many proteins and may function as a general regulator. It is required for the activity of Ypk1, a mammalian AKT/SGK kinase homolog. Our study defines potential key regulatory steps in lipid biosynthetic pathways and suggests that small metabolites may play a more general role as regulators of protein activity and function than previously appreciated.     

Mapping chromosomal proteins in vivo by formaldehyde-crosslinked-chromatin immunoprecipitation

Gene regulation is a complex process. Numerous factors appear to be required for the accurate temporal and spatial regulation of each gene. Often these factors are assembled into multiprotein complexes, contributing to specific gene regulation events. Understanding how all these factors are organized in the chromosome and how their function is regulated in vivo is a challenging task. One of the most useful techniques for studying this level of gene regulation is the in vivo fixation by formaldehyde crosslinking of proteins to proteins and proteins to DNA, followed by immunoprecipitation of the fixed material.