Hypoxia is thought to be a major cause of failure in cancer treatment. In this paper, we report methods transposable to clinical practice, for identifying hypoxic tumour cells. They consist of histochemical tests for revealing lactate dehydrogenase activity, endogenous lactate and accumulation of neutral fat. An ascites tumour (Yoshida hepatoma) and a solid tumour (Ehrlich carcinoma) were used as the experimental models. A gel film technique was used for visualizing lactate dehydrogenase and "nothing dehydrogenase" (or endogenous lactate). The fluorescent dyes Nile Red and Acridine Orange were used to demonstrate lipid accumulation and to visualize the tumour morphology, respectively. Tumour cells at the edge of areas of necrosis and at a distance of about 130 microns from a blood vessel were presumed to be hypoxic and showed the following features: 1) a dark blue granular pattern of lactate dehydrogenase (LDH) activity, ascribed to intense activity of the LDH5 and/or LDHk isoenzymes bound to membranous structures; 2) an intense granular positivity of "Nothing Dehydrogenase" due to high concentrations of endogenous lactate; 3) neutral lipid droplets emitting an intense yellow fluorescence in Nile Red-stained preparations; 4) a yellow cytoplasmic fluorescence in Acridine Orange-stained sections, attributable to a low cellular RNA content. Electron microscopy revealed moderately osmiophilic lipid globules in close association with damaged mitochondria. Better oxygenated cells showed: (a) a reddish-blue diffuse pattern of LDH, ascribed to moderately active soluble LDH isoenzymes containing H subunits; (b) almost no "Nothing Dehydrogenase" positivity; (c) no cytoplasmic lipid droplets; and (d) an intense orange-red fluorescence in the cytoplasm of Acridine Orange-stained specimens, due to high concentrations of cellular RNA. Nile Red fluorescence showed that the lipids of the solid tumour membranes were more hydrophobic than in the normal surrounding tissue. This suggests that there are abnormal domains of neutral lipids in the tumour cell membranes. In solid tumours, cells with the characteristics attributable to hypoxia were usually observed on the edge of necrosis of cuff-like formations. In very advanced growth stages, however, they were also seen surrounding (and occasionally clogging) blood vessels, or in tentacular formations coming from a necrosis border and polarized towards the vessels. Lipid-loaded cells were also seen in blood vessels distant from the tumour. These observations point towards a chemotactic process of hypoxic cells towards better environments.
Histochemical probes for the detection of hypoxic tumour cells.
BUCETA SANDE DE FREITAS, MARIA ISABEL;BARNI, SERGIO;BERTONE, VITTORIO;ROVETA, GIANNA;GERZELI, GIUSEPPE;
1990-01-01
Abstract
Hypoxia is thought to be a major cause of failure in cancer treatment. In this paper, we report methods transposable to clinical practice, for identifying hypoxic tumour cells. They consist of histochemical tests for revealing lactate dehydrogenase activity, endogenous lactate and accumulation of neutral fat. An ascites tumour (Yoshida hepatoma) and a solid tumour (Ehrlich carcinoma) were used as the experimental models. A gel film technique was used for visualizing lactate dehydrogenase and "nothing dehydrogenase" (or endogenous lactate). The fluorescent dyes Nile Red and Acridine Orange were used to demonstrate lipid accumulation and to visualize the tumour morphology, respectively. Tumour cells at the edge of areas of necrosis and at a distance of about 130 microns from a blood vessel were presumed to be hypoxic and showed the following features: 1) a dark blue granular pattern of lactate dehydrogenase (LDH) activity, ascribed to intense activity of the LDH5 and/or LDHk isoenzymes bound to membranous structures; 2) an intense granular positivity of "Nothing Dehydrogenase" due to high concentrations of endogenous lactate; 3) neutral lipid droplets emitting an intense yellow fluorescence in Nile Red-stained preparations; 4) a yellow cytoplasmic fluorescence in Acridine Orange-stained sections, attributable to a low cellular RNA content. Electron microscopy revealed moderately osmiophilic lipid globules in close association with damaged mitochondria. Better oxygenated cells showed: (a) a reddish-blue diffuse pattern of LDH, ascribed to moderately active soluble LDH isoenzymes containing H subunits; (b) almost no "Nothing Dehydrogenase" positivity; (c) no cytoplasmic lipid droplets; and (d) an intense orange-red fluorescence in the cytoplasm of Acridine Orange-stained specimens, due to high concentrations of cellular RNA. Nile Red fluorescence showed that the lipids of the solid tumour membranes were more hydrophobic than in the normal surrounding tissue. This suggests that there are abnormal domains of neutral lipids in the tumour cell membranes. In solid tumours, cells with the characteristics attributable to hypoxia were usually observed on the edge of necrosis of cuff-like formations. In very advanced growth stages, however, they were also seen surrounding (and occasionally clogging) blood vessels, or in tentacular formations coming from a necrosis border and polarized towards the vessels. Lipid-loaded cells were also seen in blood vessels distant from the tumour. These observations point towards a chemotactic process of hypoxic cells towards better environments.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.