Circulating collagen is catabolized by endocytosis mainly by endothelial cells of endocardium in cod (Gadus morhua)

The cells responsible for the clearance of collagen were studied in cod. Cod collagen labelled with the lysosomal trap-label ¹²⁵I-tyramine cellobiose was cleared from the circulation with a t_1/2 of 15 min. 1 h After injection 75%, 17% and 8% of the label were recovered in the heart, liver and blood, respectively. 24 h After administration of collagen labelled conventionally with ¹²⁵I to allow escape of labelled degradation product from the site of uptake, 80% of the label had left the heart, signifying degradation. When collagen was tagged with ¹²⁵I-tyramine cellobiose, heart-associated radioactivity did not decrease after 24 h, indicating intralysosomal degradation. Fluorescence microscopy revealed that i.v. injected fluorescently-labelled collagen accumulated in discrete vesicles of cells lining the endocardial blood space of both atrium and ventricle. Conventional and immuno-electron microscopy showed that these cells contained numerous coated pits and vesicles reflecting active endocytosis, and that ligand lined the limiting membrane of early endosomes. Intravenously injected 2 m latex accumulated mainly in kidney. We conclude that the population of non-macrophagic endocardial cells are important for the turnover of collagen in cod. These cells therefore resemble sinusoidal endothelial cells of salmon kidney and mammalian liver.     

Intracellular transport and degradation of I-labelled denatured serum albumin in isolated nonparenchymal rat liver cells

The intracellular movement, following uptake of ¹²⁵I-labelled denatured serum albumin into nonparenchymal liver cells, was followed by means of subcellular fractionation. Isolated nonparenchymal rat liver cells were prepared by means of differential centrifugation. The cells were homogenized in a sonifier and the cytoplasmic extract subjected to isopycnic centrifugation in a sucrose gradient. The intracellular movement of the labelled albumin was followed by comparing the distribution profile of radioactivity in the sucrose gradient with those of marker enzymes for plasma membrane and lysosomes. The distribution profiles for radioactivity after the cells had been exposed to the labelled denatured albumin for different time periods indicated that the radioactivity was first associated with subcellular fractions of lower modal densities than the lysosomes. With time of incubation the radioactivity moved towards higher densities. After prolonged incubations in the absence of extracellular labelled denatured albumin the radioactivity peak coincided with that of the lysosomal marker β-acetylglucosaminidase. When the cells were treated with the lysosomal inhibitor leupeptin, degradation of the labelled albumin was decreased, resulting in a massive intracellular accumulation of radioactivity. The radioactivity peak coincided with the peak of activity for the lysosomal marker β-acetylglucosaminidase, suggesting lysosomal degradation.     

Transport and metabolism of thiamine in rat brain cortex in vitro

1. Aerobic incubation at 37° of rat brain-cortex slices in Krebs–Ringer phosphate medium containing glucose and labelled thiamine results in accumulation in the tissue of labelled thiamine and labelled thiamine phosphates. The concentration of the labelled thiamine in the tissue cell water increases with increase of external labelled thiamine concentration in an approximately linear manner, the concentration ratio for labelled thiamine (tissue:medium) exceeding unity with low external thiamine concentrations (e.g. 0·2μm) and diminishing to about unity as the external thiamine concentration is increased to 1μm. The concentration of labelled phosphorylated thiamine in the tissue is at least double that of the labelled thiamine present and its amount increases with increase of external thiamine concentration. Labelled phosphorylated thiamine appears in the medium, its amount being about one-fifteenth of that in the tissue. Phosphorylation of thiamine in the tissue proceeds during incubation for 3hr. and, with an external labelled thiamine concentration of 0·2μm, about 48% conversion of thiamine takes place. 2. In the presence of ouabain (0·1mm), which does not inhibit thiamine phosphorylation in rat brain extract, there is a fall in the uptake of labelled thiamine by brain-cortex slices and the concentration ratio for the labelled thiamine (tissue:medium) falls to below unity. Anaerobiosis, lack of Na⁺ or the presence of Amprol (0·01mm) leads to marked inhibition of thiamine phosphorylation, and the concentration ratio for labelled thiamine (tissue:medium) falls to about unity. The facts lead to the conclusion that thiamine is conveyed into the brain cell against a concentration gradient by an energy-assisted process mediated by a membrane carrier. Pyri-thiamine is a marked inhibitor of thiamine phosphorylation in brain extract. 3. Thiamine monophosphate and thiamine diphosphate inhibit thiamine phosphorylation in brain extract. They diminish `total' thiamine (free and phosphorylated) uptake into brain-cortex slices and inhibit the transport of thiamine into the brain cell, possibly by competition for the carrier. 4. Phosphorylation of labelled thiamine in brain extract is brought about not only by adenosine triphosphate (in the presence of Mg²⁺) but apparently by adenosine diphosphate and uridine triphosphate.     

Characterization of calcium accumulation in the brain of rats administered orally calcium: The significance of energy-dependent mechanism

Primary cultures of rat hepatocytes maintained on different matrix proteins such as collagen (Co IV) fibronectin (Fn), Laminin (Ln) or different tissue biomatrices were metabolically labelled with ³⁵[S]-SO₄ and the synthesis of sulphated proteoglycans was studied. The incorporation of the label into total glycosaminoglycan (GAG) was significantly higher in cells maintained on Co IV compared to those maintained on Fn or Ln. Similarly the incorporation of label was maximum in those cells maintained on the aortic biomatrix compared to liver or mammary gland biomatrix. About 80–95% of the GAG synthesised and secreted by cells maintained on individual matrix proteins and liver biomatrix was heparan sulphate (HS). But in the case of cells maintained on collagen IV aortic or mammary biomatrix in addition to HS, significant amount of chondroitin sulphate (CS) was also found. Nearly 50% of the total ³⁵[S]-GAG was associated with the cell layer after 24 h in culture in the case of cells maintained on individual matrix protein while those maintained on tissue biomatrix, retained about 70% of the ³⁵[S]-labelled proteoglycans (PG) with the cell layer. Analysis of the cell surface ³⁵[S]-labelled proteoglycans isolated from cells maintained on different biomatrix showed that it is a hybrid proteoglycan consisting of CS and HS. While the PG isolated from cells maintained on liver biomatrix consists of HS and CS in the ratio of 3:2 that from cells maintained on aorta or mammary gland matrix was about 2:3 indicating an alteration in the nature of the cell surface PGs produced by cells maintained on different tissue biomatrix. These results indicate that depending on the nature of the matrix substratum with which the cells are in contact, the nature and quantity of sulphated proteoglycans produced by hepatocytes vary.     

Glucagon control of cyclic AMP accumulation in isolated intact rat liver parenchymal cells in vitro

Cyclic AMP levels were measured in suspensions of isolated rat liver parenchymal cells during incubation in vitro. Glucagon caused a rapid elevation of cyclic AMP content. With 1.4·10⁻⁶ M (5 μg/ml) of the hormone the levels increased about 10-fold during the first minute, thereafter the elevation was less rapid. Maximal values were reached at 5–10 min. Theophylline slightly increased the basal cyclic AMP levels, and markedly augmented the response to glucagon. Teh major part of the cyclic AMP was located within cells, but a siginificant fraction was present in the incubation medium, and the relative amount present extracellularly increased with incubation time. Significant elevation of the cyclic AMP levels was produced by glucagon 1.4·10⁻¹⁰M, and half-maximal stimulation occured at about 2·10⁻⁹ M. The initial rate of cyclic AMP accumulation was such more rapid in the parenchymal cells than in liver slices, and the maximal levels obtained were about 3 times higher (comparisons based on the finding that 1 mg liver tissue contains about 10⁵ parenchymal cells). It is concluded that preparations of parenchymal liver cells are useful in the study of glucagon actions on liver tissue.     

The activity of the pentose phosphate pathway in isolated liver cells

Isolated liver cells have been used to assess the relative contribution of the pentose phosphate pathway to glucose metabolism. The incorporation of carbon from specifically labelled glucose into ¹⁴CO₂ by isolated cells gave values (μg.atoms/g.cells/hr) of: C-1, 7.9; C-6, 1.3; C-U, 3.4. The corresponding figures for liver slices were: C-1, 2.3; C-6, 1.6; C-U, 3.0. The most striking difference was the 3.5-fold increase in the oxidation of C-1 of glucose. Isolated cells retain more than 50% of ATP and have a content of intermediates of the glycolytic pathway closely similar to freeze-clamped liver. The relative importance of the pentose phosphate pathway in isolated liver cells, approximately 16% of glucose catabolised, is consistent with the enzyme profile of liver and the reductive synthetic reactions of the tissue.     

Exchange transamination and the metabolism of glutamate in brain

1. Experiments were performed to throw light on why the incorporation of ¹⁴C from labelled carbohydrate precursors into glutamate has been found to be more marked in brain than in other tissues. 2. Rapid isotope exchange between labelled glutamate and unlabelled α-oxoglutarate was demonstrated in brain and liver mitochondrial preparations. In the presence but not in the absence of α-oxoglutarate the yield of ¹⁴CO₂ from [1-¹⁴C]glutamate exceeded the net glutamate removal, and the final relative specific activities of the two substrates indicated that complete isotopic equilibration had occurred. Also, when in a brain preparation net glutamate removal was inhibited by malonate, isotope exchange between [1-¹⁴C]glutamate and α-oxoglutarate and the formation of ¹⁴CO₂ were unaffected. 3. The time-course of isotope exchange between labelled glutamate and unlabelled α-oxoglutarate was followed in uncoupled brain and liver mitochondrial fractions, and the rate of exchange calculated by a computer was found to be 3–8 times more rapid than the maximal rate of utilization of the two substrates. 4. The physiological situation was imitated by the continuous infusion of small amounts of α-oxo[1-¹⁴C]glutarate into brain homogenate containing added glutamate. The fraction of ¹⁴C infused that was retained in the glutamate pool depended on the size of the latter, and the final relative specific activities of the two substrates indicated almost complete isotope exchange. Isotopic equilibration also occurred when α-oxoglutarate was generated from pyruvate through the tricarboxylic acid cycle in a brain mitochondrial preparation containing [1-¹⁴C]glutamate. 5. The differences in the incorporation of ¹⁴C from labelled glucose into the glutamate of brain and liver are discussed in terms of the rates of isotope exchange, the glutamate pool sizes and the rates of formation of labelled α-oxoglutarate in the two tissues. It is concluded that the differences between tissues in the incorporation of glucose carbon into glutamate reflect features of their metabolism largely unrelated to that of glutamate.     

WSX-1 Signalling Inhibits CD4+ T Cell Migration to the Liver during Malaria Infection by Repressing Chemokine-Independent Pathways

IL-27 is an important and non-redundant regulator of effector T cell accumulation in non-lymphoid tissues during infection. Using malaria as a model systemic pro-inflammatory infection, we demonstrate that the aberrant accumulation of CD4⁺ T cells in the liver of infected IL27R^−/− (WSX-1^−/−) mice is a result of differences in cellular recruitment, rather than changes in T cell proliferation or cell death. We show that IL-27 both inhibits the migratory capacity of infection-derived CD4⁺ T cells towards infection-derived liver cells, but also suppresses the production of soluble liver-derived mediator(s) that direct CD4⁺ T cell movement towards the inflamed tissue. Although CCL4 and CCL5 expression was higher in livers of infected WSX-1^−/− mice than infected WT mice, and hepatic CD4⁺ T cells from WSX-1^−/− mice expressed higher levels of CCR5 than cells from WT mice, migration of CD4⁺ T cells to the liver of WSX-1^−/− mice during infection was not controlled by chemokine (R) signalling. However, anti-IL-12p40 treatment reduced migration of CD4⁺ T cells towards infection-derived liver cells, primarily by abrogating the hepatotropic migratory capacity of T cells, rather than diminishing soluble tissue-derived migratory signals. These results indicate that IL-27R signalling restricts CD4⁺ T cell accumulation within the liver during infection primarily by suppressing T cell chemotaxis, which may be linked to its capacity to repress Th1 differentiation, as well as by inhibiting the production of soluble, tissue-derived chemotaxins.     

All-In-One: Advanced preparation of Human Parenchymal and Non-Parenchymal Liver Cells

Background & Aims

Liver cells are key players in innate immunity. Thus, studying primary isolated liver cells is necessary for determining their role in liver physiology and pathophysiology. In particular, the quantity and quality of isolated cells are crucial to their function. Our aim was to isolate a large quantity of high-quality human parenchymal and non-parenchymal cells from a single liver specimen.

Methods

Hepatocytes, Kupffer cells, liver sinusoidal endothelial cells, and stellate cells were isolated from liver tissues by collagenase perfusion in combination with low-speed centrifugation, density gradient centrifugation, and magnetic-activated cell sorting. The purity and functionality of cultured cell populations were controlled by determining their morphology, discriminative cell marker expression, and functional activity.

Results

Cell preparation yielded the following cell counts per gram of liver tissue: 2.0±0.4×10⁷ hepatocytes, 1.8±0.5×10⁶ Kupffer cells, 4.3±1.9×10⁵ liver sinusoidal endothelial cells, and 3.2±0.5×10⁵ stellate cells. Hepatocytes were identified by albumin (95.5±1.7%) and exhibited time-dependent activity of cytochrome P450 enzymes. Kupffer cells expressed CD68 (94.5±1.2%) and exhibited phagocytic activity, as determined with 1μm latex beads. Endothelial cells were CD146⁺ (97.8±1.1%) and exhibited efficient uptake of acetylated low-density lipoprotein. Hepatic stellate cells were identified by the expression of α-smooth muscle actin (97.1±1.5%). These cells further exhibited retinol (vitamin A)-mediated autofluorescence.

Conclusions

Our isolation procedure for primary parenchymal and non-parenchymal liver cells resulted in cell populations of high purity and quality, with retained physiological functionality in vitro. Thus, this system may provide a valuable tool for determining liver function and disease.     

CD8+ T-Cells Expressing Interferon Gamma or Perforin Play Antagonistic Roles in Heart Injury in Experimental Trypanosoma Cruzi-Elicited Cardiomyopathy

In Chagas disease, CD8⁺ T-cells are critical for the control of Trypanosoma cruzi during acute infection. Conversely, CD8⁺ T-cell accumulation in the myocardium during chronic infection may cause tissue injury leading to chronic chagasic cardiomyopathy (CCC). Here we explored the role of CD8⁺ T-cells in T. cruzi-elicited heart injury in C57BL/6 mice infected with the Colombian strain. Cardiomyocyte lesion evaluated by creatine kinase-MB isoenzyme activity levels in the serum and electrical abnormalities revealed by electrocardiogram were not associated with the intensity of heart parasitism and myocarditis in the chronic infection. Further, there was no association between heart injury and systemic anti-T. cruzi CD8⁺ T-cell capacity to produce interferon-gamma (IFNγ) and to perform specific cytotoxicity. Heart injury, however, paralleled accumulation of anti-T. cruzi cells in the cardiac tissue. In T. cruzi infection, most of the CD8⁺ T-cells segregated into IFNγ⁺ perforin (Pfn)^neg or IFNγ^negPfn⁺ cell populations. Colonization of the cardiac tissue by anti-T. cruzi CD8⁺Pfn⁺ cells paralleled the worsening of CCC. The adoptive cell transfer to T. cruzi-infected cd8 ^−/− recipients showed that the CD8⁺ cells from infected ifnγ^−/− pfn ^+/+ donors migrate towards the cardiac tissue to a greater extent and caused a more severe cardiomyocyte lesion than CD8⁺ cells from ifnγ ^+/+ pfn ^−/− donors. Moreover, the reconstitution of naïve cd8 ^−/− mice with CD8⁺ cells from naïve ifnγ ^+/+ pfn ^−/− donors ameliorated T. cruzi-elicited heart injury paralleled IFNγ⁺ cells accumulation, whereas reconstitution with CD8⁺ cells from naïve ifnγ ^−/− pfn ^+/+ donors led to an aggravation of the cardiomyocyte lesion, which was associated with the accumulation of Pfn⁺ cells in the cardiac tissue. Our data support a possible antagonist effect of CD8⁺Pfn⁺ and CD8⁺IFNγ⁺ cells during CCC. CD8⁺IFNγ⁺ cells may exert a beneficial role, whereas CD8⁺Pfn⁺ may play a detrimental role in T. cruzi-elicited heart injury.     

The site at which 4-iodoacetamidosalicylate reacts with glutamate dehydrogenases

1. Bovine, porcine and chicken liver glutamate dehydrogenases were irreversibly inhibited by a tenfold excess of radioactive 4-iodoacetamidosalicylic acid at pH7.5. 2. Inhibition was accompanied by the covalent incorporation of 1.1 mol of labelled inhibitor/mol of polypeptide chain. Acid hydrolysis yielded N^ε-carboxymethyl-lysine as the sole labelled amino acid. No labelled S-carboxymethylcysteine was recovered from the bovine or porcine enzymes. 3. The labelled bovine enzyme was hydrolysed with trypsin. The radioactivity was found at lysine-126 in a peptide comprising residues 119–130 of the sequence. 4. The amino acid compositions of the tryptic peptides containing labelled lysine from the porcine and chicken enzymes were similar to that of the bovine peptide.     

Studies on lipogenesis in vivo: Fatty acid and cholesterol synthesis in hyperglycaemic-obese mice

1. Lipogenesis has been studied in intact genetically obese mice by measuring the incorporation of a single oral dose of 250mg. of [U-¹⁴C]glucose into fatty acid and cholesterol in the liver and extrahepatic tissues. Studies were also carried out with [U-¹⁴C]glucose added to the diet and fed for 24hr. With either method of isotope administration, the conversion of [U-¹⁴C]glucose into fatty acid was greatly elevated in the livers of the obese mice. In contrast, conversion of the single dose of [¹⁴C]glucose into fatty acid in extrahepatic tissues of obese mice was only half that occurring in the non-obese litter mates. When [¹⁴C]glucose was given in the diet for 24hr. the total accumulation of labelled fatty acid in extrahepatic tissues of obese mice was slightly less than in the non-obese. Uptake of labelled glucose and conversion into fatty acid in adipose tissue of the obese mice decreased with age. 2. Conversion of the single dose of [¹⁴C]glucose into liver cholesterol was comparable in obese and non-obese mice fed on a purified low-fat diet. However, obese mice given this diet for 12 weeks accumulated 1·54% of cholesterol in the liver compared with 0·29% in the non-obese litter mates. This accumulation apparently resulted from a decrease in removal of cholesterol from the liver, rather than an increased synthesis. 3. Conversion of the single dose of [¹⁴C]glucose into extrahepatic fatty acid was decreased by 18hr. starvation proportionally as much in obese as in non-obese mice. The decrease in liver fatty acid synthesis caused by starvation also was considerable in obese mice, although somewhat less marked than in the non-obese. 4. The metabolic derangements in the liver could be more fundamental to the development of the obesity than the changes seen in extrahepatic tissues.     

Assessing in vitro stem‐cell function and tracking engraftment of stem cells in ischaemic hearts by using novel iRFP gene labelling

Near‐infrared fluorescence (NIRF) imaging by using infrared fluorescent protein (iRFP) gene labelling is a novel technology with potential value for in vivo applications. In this study, we expressed iRFP in mouse cardiac progenitor cells (CPC) by lentiviral vector and demonstrated that the iRFP‐labelled CPC (CPC^iRFP) can be detected by flow cytometry and fluorescent microscopy. We observed a linear correlation in vitro between cell numbers and infrared signal intensity by using the multiSpectral imaging system. CPC^iRFP injected into the non‐ischaemic mouse hindlimb were also readily detected by whole‐animal NIRF imaging. We then compared iRFP against green fluorescent protein (GFP) for tracking survival of engrafted CPC in mouse ischaemic heart tissue. GFP‐labelled CPC (CPC^GFP) or CPC labelled with both iRFP and GFP (CPC^{iRFP GFP}) were injected intramyocardially into mouse hearts after infarction. Three days after cell transplantation, a strong NIRF signal was detected in hearts into which CPC^{iRFP GFP}, but not CPC^GFP, were transplanted. Furthermore, iRFP fluorescence from engrafted CPC^{iRFP GFP} was detected in tissue sections by confocal microscopy. In conclusion, the iRFP‐labelling system provides a valuable molecular imaging tool to track the fate of transplanted progenitor cells in vivo.     

Fasting Enhances TRAIL-Mediated Liver Natural Killer Cell Activity via HSP70 Upregulation

Acute starvation, which is frequently observed in clinical practice, sometimes augments the cytolytic activity of natural killer cells against neoplastic cells. In this study, we investigated the molecular mechanisms underlying the enhancement of natural killer cell function by fasting in mice. The total number of liver resident natural killer cells in a unit weight of liver tissue obtained from C57BL/6J mice did not change after a 3-day fast, while the proportions of tumor necrosis factor–related apoptosis-inducing ligand (TRAIL)⁺ and CD69⁺ natural killer cells were significantly elevated (n = 7, p <0.01), as determined by flow cytometric analysis. Furthermore, we found that TRAIL⁻ natural killer cells that were adoptively transferred into Rag-2^−/− γ chain^−/− mice could convert into TRAIL⁺ natural killer cells in fasted mice at a higher proportion than in fed mice. Liver natural killer cells also showed high TRAIL-mediated antitumor function in response to 3-day fasting. Since these fasted mice highly expressed heat shock protein 70 (n = 7, p <0.05) in liver tissues, as determined by western blot, the role of this protein in natural killer cell activation was investigated. Treatment of liver lymphocytes with 50 µg/mL of recombinant heat shock protein 70 led to the upregulation of both TRAIL and CD69 in liver natural killer cells (n = 6, p <0.05). In addition, HSP70 neutralization by intraperitoneally injecting an anti- heat shock protein 70 monoclonal antibody into mice prior to fasting led to the downregulation of TRAIL expression (n = 6, p <0.05). These findings indicate that acute fasting enhances TRAIL-mediated liver natural killer cell activity against neoplastic cells through upregulation of heat shock protein 70.     

Distribution of 103Ru—chloride in tumor-bearing animals and the mechanism for accumulation in tumor and liver

Tumor uptake rates of ¹⁰³Ru—chloride were smaller than those for ⁶⁷Ga—citrate. In three tumors and liver, ¹⁰³Ru in the mitochondrial fraction containing lysosome increased with time after the administration of ¹⁰³Ru—chloride. The concentration of ¹⁰³Ru was more dominant in connective tissue (especially inflammatory tissue) than in viable tumor tissue or in necrotic tissue. Quite large amounts of ¹⁰³Ru in the tumor and liver were bound to the acid mucopolysaccharide whose molecular masses exceeded 40,000. Behavior of this nuclide was essentially similar to that of ⁶⁷Ga.     

The Imaging of Insulinomas Using a Radionuclide-Labelled Molecule of the GLP-1 Analogue Liraglutide: A New Application of Liraglutide

Objective

This study explores a new, non-invasive imaging method for the specific diagnosis of insulinoma by providing an initial investigation of the use of ¹²⁵I-labelled molecules of the glucagon-like peptide-1 (GLP-1) analogue liraglutide for in vivo and in vitro small-animal SPECT/CT (single-photon emission computed tomography/computed tomography) imaging of insulinomas.

Methods

Liraglutide was labelled with ¹²⁵I by the Iodogen method. The labelled ¹²⁵I-liraglutide compound and insulinoma cells from the INS-1 cell line were then used for in vitro saturation and competitive binding experiments. In addition, in a nude mouse model, the use of ¹²⁵I-liraglutide for the in vivo small-animal SPECT/CT imaging of insulinomas and the resulting distribution of radioactivity across various organs were examined.

Results

The labelling of liraglutide with ¹²⁵I was successful, yielding a labelling rate of approximately 95% and a radiochemical purity of greater than 95%. For the binding between ¹²⁵I-liraglutide and the GLP-1 receptor on the surface of INS-1 cells, the equilibrium dissociation constant (K_d) was 128.8±30.4 nmol/L(N = 3), and the half-inhibition concentration (IC₅₀) was 542.4±187.5 nmol/L(N = 3). Small-animal SPECT/CT imaging with ¹²⁵I-liraglutide indicated that the tumour imaging was clearest at 90 min after the ¹²⁵I-liraglutide treatment. An examination of the in vivo distribution of radioactivity revealed that at 90 min after the ¹²⁵I-liraglutide treatment, the target/non-target (T/NT) ratio for tumour and muscle tissue was 4.83±1.30(N = 3). Our study suggested that ¹²⁵I-liraglutide was predominantly metabolised and cleared by the liver and kidneys.

Conclusion

The radionuclide ¹²⁵I-liraglutide can be utilised for the specific imaging of insulinomas, representing a new non-invasive approach for the in vivo diagnosis of insulinomas.     

Labelling of high molecular weight hyaluronan with125I-tyrosine: studiesin vitro andin vivo in the rat

Studies on the metabolism of the polysaccharide hyaluronan has previously been hampered by the lack of radioactive hyaluronan of high molecular weight (MW) and high specific activity. In the present study¹²⁵I-tyrosine (T)-labelled hyaluronan was produced after CNBr-activation of the polysaccharide. A specific activity of approximately 0.1 MBq µg^–1 was achieved using 100 µg of 0.5×10⁶ Da hyaluronan labelled for 2 h with 18 MBq¹²⁵I. The¹²⁵I-T-hyaluronan kept a high MW-profile upon gel filtration chromatography and was found to be cleared from the circulation with the kinetics and organ distribution reported for biosynthetically labelled hyaluronan of high MW. The¹²⁵I-labelled polysaccharide is also taken up by liver endothelial cells bothin vivo andin vitro, indicating that the labelling does not interfere with the binding to specific cell-surface receptors found on these cells. The intracellular degradation is slower than that earlier reported for biosynthetically labelled hyaluronan and seems to be halted at the level of low MW oligo- or mono-saccharides that eventually leave the organism via the urine. Scintigraphic images of rats after intravenous injection of¹²⁵I-T-hyaluronan showed rapid uptake in the liver and a redistribution of radioactivity from liver to urine with time. Our results indicate that the¹²⁵I-T-hyaluronan is suitable for studies of hyaluronan-metabolism in a number of ways. The gamma emitters¹²⁵I and¹³¹I are easy to monitor and can be used also forin vivo 3D-imaging using single photon emission computer tomography.Abbreviations CNBr cyanogen bromide - T-HA tyrosine-labelled hyaluronan     

Sugar uptake by the grape berry: A note on the absorption pathway

Summary ³H-glucose was fed to excised Sultana grape berries via their pedicels for up to 5 hours. Autoradigraphy showed that the label was distributed throughout the fruit within 1 hour. Microautoradiography of tissue sections taken at a number of points showed that within the pedicel the walls of cortical cells had become heavily labelled, suggesting that the cortical cell walls offered a diffusion pathway for the solutes entering the vascular system from the external aqueous solution. Transport along the pedicel was confined to the central vascular tissue with little radioactivity occurring in the cortical cells. Within the pericarp, the vascular bundles and walls of nearby parenchyma cells had become heavily labelled, indicating that the labelled solute was present within the vicinity of cell walls. The general pattern of ³H-glucose accumulation by excised berries was similar to the deposition pattern of ²⁴C-labelled photosynthate within attached fruit.     

Does ex vivo labelling of proliferating cells in colonic and vaginal mucosa reflect the S-phase fraction in vivo?

Summary The ex vivo labelling of DNA-synthesizing epithelial cells in colonic and vaginal mucosa was compared with in vivo labelling. For this purpose, in vivo S-phase cells were labelled with [³H]thymidine (Tdr) and ex vivo labelling was continued by culturing tissue specimens in bromodeoxyuridine (BrdU). Various methods of tissue culture were employed in order to improve diffusion of medium (and BrdU) in the tissue. BrdU and ³H-TdR labelling were evaluated by immunohistochemistry and autoradiography respectively. Ex vivo labelling resulted in a patchy distribution of labelled cells, which did not correspond with the ³H-TdR labelling pattern obtained in vivo. Under the described conditions ex vivo labelling does not appear to be a reliable for estimation of the proliferative activities in vivo.     

Is the movement of single cells within solid tissue masses induced by trypsinization?

Embryonic chick cells, labeled with tritiated thymidine ([³H]TdR), isolated with trypsin and allowed to “recover” or isolated without trypsin were seeded onto the surfaces of solid tissue masses in culture. Autoradiographs revealed extensive migration of single, labeled cells within the tightly packed cell masses. The ability of single cells to infiltrate solid tissue masses in culture does not, therefore, seem to depend upon prior proteolytic treatment.