Lung T. Yam

COMPARISON OF PROSTATIC AND NONPROSTATIC ACID PHOSPHATASE

Electrophoresis and ion-exchange column chromatography were used to separate the wide varieties of acid phosphatases with different biological and clinical significance. Band 0 was very strong in ascitic cells with many autophagic vacuoles, indicating a role in autophagic function. Band 1 was a membrane-bound acid phosphatase, seen mainly in the microsomal fraction. Band 3 was the major lysosomal acid phosphatase of all nonprostatic tissues. Bands 2 and 4 were antigenically identical to each other, and were observed in unusually high amounts in the prostate. The different electrophoretic mobility between bands 2 and 4 was due to their carbohydrate content. Band 5 was a characteristic enzyme of the osteoclast. The tartrate-sensitive enzymes included bands 0 through 4. Only band 5 was tartrate resistant. The tartrate-resistant acid phosphatase of erythrocytes was not detected by the electrophoresis method. Clinical applications were seen for both bands 2 and 5. Band 2 was a secretory enzyme, normally secreted into the seminal plasma. Band 2 was absorbed into the blood circulation in some prostatic cancer patients. A small amount of bands 2 and 4 was observed in nonprostatic tissues. The diagnostic value of band 2 resulted from its extremely high concentration in the prostate. Band 5 was not observed in the normal prostate. A high concentration of band 5 was observed in hairy cells, Gaucher cells, and osteoclasts. The serum level of band 5b was an indicator of osteoclastic activity in the bone. Elevation of band 5b in serum was observed in normal children during physiological bone growth, in Gauchers disease, and in malignancies metastasized to bone.

Atlas of Cytochemistry and Immunochemistry of Hematologic Neoplasms

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Immunoultrastructural Demonstration of Prostatic Acid Phosphatase Isoenzyme 2 in Prostatic Carcinoma

Human prostatic acid phosphatase isoenzyme 2 (HPAcP-2) was isolated from semen. This purified enzyme was immunized to rabbit to produce polyclonal antibodies. The specificity of the antibodies was tested by Western blot transfer method. Rabbit IgG-peroxidase conjugate was prepared from the antiserum and used to localize HPAcP-2 in prostatic carcinoma. It was found that in the tumor glandular acinus the normal basal cells were replaced by tumor cells containing reaction product. In the tumor cells, the reaction product was seen in the cisternae of rough endoplasmic reticulum (ER) and Golgi apparatus. The secretory vesicles which contained reaction product-stained granules and some amorphous material were seen to fuse with the apical plasma membrane and discharged their content into the glandular lumen. On the other hand, some secretory vesicles in the tumor cells facing to the basement membrane also discharged their similar content into the extracellular spaces. Reaction product-stained granules were found in the interstitial spaces surrounding the tumor cells. These findings suggest that HPAcP-2 is synthesized on the bound ribosomes and discharged into the cisternae of rough ER. The molecules are transported to the Golgi cisternae. After concentration and packaging, HPAcP-2 molecules are then transferred to the secretory vesicles, and discharged into the glandular lumen and to the extracellular spaces. The isoenzyme released in the extracellular space may reach the blood stream through the interstitial spaces or the lymphatic system, resulting in the elevation of serum HPAcPase level in some prostatic cancer patients.

Simultaneous Demonstration of Nonspecific Esterase and Chloroacetate Esterase in Human Blood Cells

A new cytochemical method is described for the simultaneous demonstration of nonspecific esterase in monocytes and chloracetate esterase in granulocytes. The procedure uses both alpha-naphthyl butyrate and naphthol AS-D chloroacetate as substrates and hexazotized pararosaniline as the coupler. The enzyme reaction products are highly chromogenic and their localization is precise. This method is potentially useful for the accurate diagnosis of the acute monocytic leukemias. Its advantages and limitations are also discussed.

Comparison of tartrate resistant acid phosphatase in a giant cell bone tumor and a spleen infiltrated with hairy cells

Acid phosphatase (E.C.3.1.3.2) in a giant cell bone tumor and a spleen infiltrated with hairy cells was extracted by citrate buffer and then by 0.3 mol/L NaCl. The cationic acid phosphatase in the crude extract was isolated by CM-cellulose chromatography, and further separated by high pressure liquid chromatography. The majority of the tartrate resistant acid phosphatase in the hairy cell spleen was unabsorbed on CM-cellulose and was insensitive to iron. A much larger portion of the acid phosphatase in the bone tumor, than in the spleen, was cationic and was eluted from the column by 0.8 mol/L NaCl. The cationic acid phosphatase was further separated into consecutive peaks of acid phosphatases with different sensitivity to iron. A major portion of acid phosphatase in the giant cell bone tumor was enhanced by iron, while the amounts of iron-enhanced and iron-insensitive acid phosphatase were about the same in the spleen. The differences of the phosphatases in these two types of pathologic specimens indicate the occurrence of two types of enzymes with different biological significance.

Monoclonal Antibody Specific to Acid Phosphatase Isoenzyme 4

Prostatic acid phosphatase isoenzyme 4 was purified by ion exchange column chromatography, followed by high pressure liquid chromatography. The highly purified enzyme was used to produce monoclonal antibody from immunized BALB/c mice. The antibody was specific to isoenzyme 4, with negligible affinity to isoenzyme 2. The specificity of the monoclonal antibody was evaluated by Western blot analysis and by inhibition of radioimmunoassay. Immunohistochemistry method using the antibody to isoenzyme 2 showed heavy staining on the cell surface in contrast to the even staining throughout the cytoplasm when monoclonal anti-isoenzyme 4 was used. These results reflect the secretory nature of isoenzyme 2 and the non-secretory nature of isoenzyme 4.