A one-day double-labelling technique for tissue specimens: Immunogold-silver staining forin situ hybridization combined with alkaline phosphatase-anti-alkaline phosphatase (APAAP) immunohistochemistry for antigens

Summary An improved technique is described that addresses the problems of sensitivity, specificity, the use of hazardous radioactive equipment and time consumption in immunohistochemical labelling and double labelling ofin situ hybridization of tissue specimens. It consists of a two-step protocol in which digoxigenin-uridine triphosphate (UTP) labelled riboprobes in thein situ hybridization step are visualized by the immunogold-silver staining method, and double labelling of tissue antigens is achieved by the application of an alkaline phosphatase-anti-alkaline phosphatase staining step. We tested this protocol using snap-frozen tissue sections of synovial tissue from patients with rheumatoid arthritis. The target mRNA was detected by perforin or cathepsin D riboprobes, the double labelling was performed using anti-collagen type IV and alpha-smooth muscle actin antibodies. It is concluded that, in comparison with an established three-to four-day double-labelling protocol used in many laboratories, this one-day combination is currently the most rapid assay of reliable quality for double labelling ofin situ hybridization products and tissue antigens.     

Monoclonal antibody to alkaline phosphatase from the intestinal mucosa of the harp seal, Phoca groenlandica.

1. Hybridoma secreting a monoclonal antibody APP.1 to the harp seal alkaline phosphatase (A1Ph) was obtained by fusing murine myeloma Sp 2/0 cells with the splenocytes of BALB/c mice immunized with purified isozyme K. 2. The antibody has no effect on the enzyme activity and shows a high affinity for harp seal A1Ph (KD = 8.5 x 10(-10) M). The antibody has similar affinities for the AlPh of harp seal, fur seal, common seal and deer. 3. The antibody APP.1 was coupled to Sepharose and employed in chromatographic purification of the harp seal intestinal AlPh. Alkaline phosphatase isolated on this immunosorbent has a spec. act. of 20,800 units per mg of protein. 4. The antibody-enzyme complex gives an excellent immunocytochemical labeling of tissue sections, cell cultures and smears.     

Functional interrelationships in the alkaline phosphatase superfamily: phosphodiesterase activity of Escherichia coli alkaline phosphatase

Escherichia coli alkaline phosphatase (AP) is a proficient phosphomonoesterase with two Zn(2+) ions in its active site. Sequence homology suggests a distant evolutionary relationship between AP and alkaline phosphodiesterase/nucleotide pyrophosphatase, with conservation of the catalytic metal ions. Furthermore, many other phosphodiesterases, although not evolutionarily related, have a similar active site configuration of divalent metal ions in their active sites. These observations led us to test whether AP could also catalyze the hydrolysis of phosphate diesters. The results described herein demonstrate that AP does have phosphodiesterase activity: the phosphatase and phosphodiesterase activities copurify over several steps; inorganic phosphate, a strong competitive inhibitor of AP, inhibits the phosphodiesterase and phosphatase activities with the same inhibition constant; a point mutation that weakens phosphate binding to AP correspondingly weakens phosphate inhibition of the phosphodiesterase activity; and mutation of active site residues substantially reduces both the mono- and diesterase activities. AP accelerates the rate of phosphate diester hydrolysis by 10(11)-fold relative to the rate of the uncatalyzed reaction [(k(cat)/K(m))/k(w)]. Although this rate enhancement is substantial, it is at least 10(6)-fold less than the rate enhancement for AP-catalyzed phosphate monoester hydrolysis. Mutational analysis suggests that common active site features contribute to hydrolysis of both phosphate monoesters and phosphate diesters. However, mutation of the active site arginine to serine, R166S, decreases the monoesterase activity but not the diesterase activity, suggesting that the interaction of this arginine with the nonbridging oxygen(s) of the phosphate monoester substrate provides a substantial amount of the preferential hydrolysis of phosphate monoesters. The observation of phosphodiesterase activity extends the previous observation that AP has a low level of sulfatase activity, further establishing the functional interrelationships among the sulfatases, phosphatases, and phosphodiesterases within the evolutionarily related AP superfamily. The catalytic promiscuity of AP could have facilitated divergent evolution via gene duplication by providing a selective advantage upon which natural selection could have acted.     

The medium cycle bioreactor (MCB): Monoclonal antibody production in a new economic production system

The perfusion mode of a continuous cell culture bioreactor was modified to establish a closed loop system. Eighty percent of the spent medium was re-used twice. The medium cycle bioreactor unit was operated sterile and uncomplicated without a technical retention system for the high molecular weight substances. Therefore, only 20% of the actual medium was necessary to run the recycling process. During seven days culture time in a two liter scale 5 grams of IgG₁ type monoclonal antibody was produced. During that period the cell specific productivity was constant. Renewal of proteins was omitted because the protein content in the system persisted at a high level. Therefore, self-conditioning substances of the cells were retained in the system as well as the expensive medium components (proteins with catalytic or stimulating function). Seventy to 80% of medium costs and medium quantity were saved for each medium recycling step. Only cheap metabolites that are consumed by the cells had to be supplemented. Uptake rates of glucose and amino acids were calculated to establish a suitable supplementation mixture for the recirculated medium.     

Seasonal changes in alkaline phosphatase activity of bacteria and microalgae in Lake Pavin (Massif Central,France)

Seasonal changes in alkalinephosphatase activity of bacteria and microalgae werestudied in the dimictic Lake Pavin (Massif Central,France), to test whetherthis activity is primarily algal or bacterial andwhether the APA presents seasonal variations coupledwith abiotic and biotic variables. Samples werecollected at different depths from May 1992 to May1993. The specific phosphatase activities wereanalysed spectrophotometrically with p-NitrophenylPhosphate (p-NPP) as substrate and were related to theprotein concentrations. No correlation was foundbetween alkaline phosphatase activity and solublereactive phosphorus (SRP) concentrations across anannual cycle. The specific activities of the smallclass (0.2–1.2 m) were the highest and thecontribution of this picoplanktonic size class(0.2–1.2 m) increased with depth. In addition, thelinear correlations between alkaline phosphataseactivity and protein concentration seemed to indicatethat most of these enzymes are constitutive. However,it cannot be excluded that the high phosphorusconcentrations repress APA.Finally, the measure of APA does not seem to be avalid quantitative test of the deficiency ofphosphorus for aquatic microorganisms.     

Effects of 100 GHz radiation on alkaline phosphatase activity and antigen–antibody interaction

Equipment that generates microwave radiation (MWR) spanning the frequency range of 300 MHz–100 GHz is becoming more common. While MWR lacks sufficient energy to break chemical bonds, the disagreement as to whether MWR exposure is detrimental to cellular dysfunction may be difficult to clarify using complex systems such as whole animals, cells, or cell extracts. Recently, the high frequency range of terahertz (THz) radiation has been explored and sources of radiation and its detectors have been developed. THz radiation is associated with the frequency interval from 100 GHz to 20 THz and constitutes the next frontier in imaging science and technology. In the present study, we investigated the effect of radiation in the low frequency THz range (100 GHz) on two defined molecular interactions. First, the interaction of soluble or immobilized calf alkaline phosphatase with the substrate p‐nitrophenylphosphate and second, the interaction between an antibody (mouse monoclonal anti‐DNP) and its antigen (DNP). Irradiation of enzyme either prior to addition of substrate or during the enzymatic reaction resulted in small but significant reductions in enzyme activity. These differences were not observed if the enzyme had previously been immobilized onto plastic microwells. Exposure of immobilized antigen to radiation did not influence the ability of the antigen to interact with antibody. However, irradiation appeared to decrease the stability of previously formed antigen–antibody complexes. Our data suggest that 100 GHz radiation can induce small but statistically significant alterations in the characteristics of these two types of biomolecular interactions. Bioelectromagnetics 30:167–175, 2009. © 2008 Wiley‐Liss, Inc.     

Inhibition of alkaline phosphatase activity by okadaic acid, a protein phosphatase inhibitor

This paper reports on a potential physiological target of okadaic acid (OA), the toxin metabolite responsible for shellfish poisoning and, consequently, human intoxication. OA is a potent promoter of tumor activity, most likely by inhibiting protein phosphatase 1 and 2A (Adv. Cancer. Res. 61 (1993) 143). However, all of its cellular targets have not yet been characterized. The interaction of OA with alkaline phosphatase (ALP) has been investigated in view of its protein phosphatase inhibition activity. Kinetic analysis of ALP from Escherichia coli, human placental and calf intestinal ALP has shown that OA acts as a non-competitive inhibitor of ALP. The bacterial enzyme displays a higher affinity for OA (K(i) 360 nM) than the eukaryotic proteins (human placental ALP, K(i) 2.05 microM; calf intestinal ALP, K(i) 3.15 microM). The inhibition by OA suggests a putative role of ALP in the phosphorylation status, through regulation of the phosphorylation/dephosphorylation equilibrium of proteins with phosphoseryl or phosphothreonyl residues.     

Imaging of alkaline phosphatase activity in bone tissue

The purpose of this study was to develop a paradigm for quantitative molecular imaging of bone cell activity. We hypothesized the feasibility of non-invasive imaging of the osteoblast enzyme alkaline phosphatase (ALP) using a small imaging molecule in combination with (19)Flourine magnetic resonance spectroscopic imaging ((19)FMRSI). 6, 8-difluoro-4-methylumbelliferyl phosphate (DiFMUP), a fluorinated ALP substrate that is activatable to a fluorescent hydrolysis product was utilized as a prototype small imaging molecule. The molecular structure of DiFMUP includes two Fluorine atoms adjacent to a phosphate group allowing it and its hydrolysis product to be distinguished using (19)Fluorine magnetic resonance spectroscopy ((19)FMRS) and (19)FMRSI. ALP-mediated hydrolysis of DiFMUP was tested on osteoblastic cells and bone tissue, using serial measurements of fluorescence activity. Extracellular activation of DiFMUP on ALP-positive mouse bone precursor cells was observed. Concurringly, DiFMUP was also activated on bone derived from rat tibia. Marked inhibition of the cell and tissue activation of DiFMUP was detected after the addition of the ALP inhibitor levamisole. (19)FMRS and (19)FMRSI were applied for the non-invasive measurement of DiFMUP hydrolysis. (19)FMRS revealed a two-peak spectrum representing DiFMUP with an associated chemical shift for the hydrolysis product. Activation of DiFMUP by ALP yielded a characteristic pharmacokinetic profile, which was quantifiable using non-localized (19)FMRS and enabled the development of a pharmacokinetic model of ALP activity. Application of (19)FMRSI facilitated anatomically accurate, non-invasive imaging of ALP concentration and activity in rat bone. Thus, (19)FMRSI represents a promising approach for the quantitative imaging of bone cell activity during bone formation with potential for both preclinical and clinical applications.     

Fluorometric measurement of alkaline phosphatase activity in algae

SUMMARY. Using both cultures of algae and natural populations, alkaline phosphatase activity located on the cell surface has been measured by a fluorometric procedure. This was done in order to establish optimum standard conditions for the measurement of this activity as an indicator of phosphorus deficiency and to provide a means of interpreting alkaline phosphatase measurements on natural phytoplankton populations. A concentration of 10 μM o-methylfluorescein phosphate saturates or nearly saturates the reaction in a variety of situations. In most trials, rates increased with temperature to or beyond 35°C. Optimum pH values in the range 7–10 were observed. In six of the algae examined, maximum alkaline phosphatase activities were dependent on external calcium at 100 μM or more. One alga, Synura uvella , showed acid phosphatase activity, peaking at pH 5–6, induced by phosphorus deficiency. Based on comparisons between P-sufficient and P-deficient cultures, alkaline phosphatase activities in excess of 0.1 μmol o-methylfluorescein phosphate hydrolysed per mg dry weight per h or 0.1 μmol per μg ATP per h are suggested as indicative of phosphorus deficiency.     

Effect of Zn(II) and Mg(II) on phosphohydrolytic activity of rat matrix-induced alkaline phosphatase

Rat matrix-induced alkaline phosphatase is an enzyme which requires magnesium and zinc ions for its maximal activity. Two Zn(II) ions and one Mg(II) ion are bound to each subunit of native dimeric enzyme. The presence of magnesium ion (10-100 microM) or zinc ion (7-20 nM) alone is sufficient to stimulate apoenzyme activity. However maximal activity (264 U/mg) requires the presence of both ions. Binding of Zn(II) ions to the Mg(II) binding site causes a strong inhibition of the apoenzyme while the binding of Mg(II) on Zn(II) binding site is not sufficient to stimulate PNPPase activity of the apoenzyme. Binding of both ions to the enzyme molecule did not change the apparent dissociation constant for PNPP hydrolysis.     

An in vitro production of bone specific alkaline phosphatase

Induced alkaline phosphatase has been extracted from osteosarcoma cells grown in tissue culture medium. The extracted enzyme has been purified. Using electrophoresis, inhibition studies, and thermolability, the enzyme was categorized as alkaline phosphatase of osseous origin. Antibodies to this enzyme were reacted against alkaline phosphatase extracted from cadaveric bone, liver, intestine, kidney and fresh placenta. The antibodies were specific against alkaline phosphatase of osseous origin only. No cross-reaction occurred with the enzyme extracted from other sources. The data derived from these studies indicate that alkaline phosphatase of bone is a specific enzyme of osseous tissue. Furthermore, the enzyme has specific antigenic and other properties which distinguish it from alkaline phosphatases from other sources. A model for in vitro production of a specific alkaline phosphatase of bone is presented.     

Acid and alkaline phosphatase activity in Trypanosoma cruzi epimastigotes

Phosphatase activity in intact Trypanosoma cruzi epimastigotes has been demonstrated. After subcellular fractionation three activities were characterized: (a) a membrane-bound microsomal acid activity with an optimum pH of 4.0 and a Km of 1.2 mM, strongly inhibited by tartrate and fluoride; (b) a soluble cytosolic acid activity with an optimum pH of 5.5 and a Km of 0.95 mM, strongly inhibited by p-hydroxymercuribenzoate, EDTA and copper ions and activated by cyanide, manganese and magnesium ions; and (c) a soluble cytosolic alkaline activity with an optimum pH of 8.0 and a Km of 3.8 mM, inhibited by p-hydroxymercuribenzoate, fluoride, EDTA, and copper, calcium and zinc ions. This activity was increased by magnesium and manganese ions.