Effects of streptozotocin on pancreatic islet β-cell apoptosis and glucose metabolism in zebrafish larvae

Type 1 diabetes is characterized by an increase in blood glucose levels resulting from damage to β cells in pancreatic islets and the consequent absolute insufficiency of insulin. Animal models of type 1 diabetes were usually established using drugs toxic to β cells, such as streptozotocin (STZ). To...

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Bibliographic Details
Published in:Fish physiology and biochemistry 2020-06, Vol.46 (3), p.1025-1038
Main Authors: Wang, Xue, Yang, Xue-liang, Liu, Ke-chun, Sheng, Wen-long, Xia, Qing, Wang, Rong-chun, Chen, Xi-qiang, Zhang, Yun
Format: Article
Language:English
Subjects:
Amputation
Animal Anatomy
Animal Biochemistry
Animal Fins - drug effects
Animal Fins - physiology
Animal models
Animal Physiology
Animals
Apoptosis
Apoptosis - drug effects
Beta cells
Biomedical and Life Sciences
Blood glucose
Blood Glucose - drug effects
Control
Danio rerio
Diabetes
Diabetes mellitus (insulin dependent)
Female
Fins
Fluorescence
Freshwater & Marine Ecology
Freshwater fishes
Gene expression
Glucose
Glucose - metabolism
Glucose transporter
Histology
Hyperglycemia
Hyperglycemia - chemically induced
Hyperglycemia - metabolism
Immunohistochemistry
Injection
Insulin
Insulin - metabolism
Insulin-Secreting Cells - drug effects
Larva
Larvae
Life Sciences
Male
Metabolism
Morphology
Pancreas
Regeneration
Regeneration (biological)
Regeneration - drug effects
Streptozocin
Streptozocin - pharmacology
Zebrafish
Zoology
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Summary:Type 1 diabetes is characterized by an increase in blood glucose levels resulting from damage to β cells in pancreatic islets and the consequent absolute insufficiency of insulin. Animal models of type 1 diabetes were usually established using drugs toxic to β cells, such as streptozotocin (STZ). To assess the application of zebrafish larvae in diabetes research, we explore the effects of STZ on pancreatic islets and glucose metabolism in zebrafish larvae. STZ was microinjected into the pericardial cavity of zebrafish larvae on alternate days for three times. At 2 days after the whole series of STZ injection (12 dpf), free-glucose level in larvae tissue shows a significant increase, and the fluorescence signal in immunohistochemistry, which indicates the insulin expression, was significantly weaker compared with the solution-injected control. Obvious apoptosis signals were also observed in the location of pancreatic islet, and insulin content decreased to be undetectable in STZ-injected larvae. Gene expression level of ins decreased to half of the solution injection control and that of casp3a was upregulated by 2.20-fold. Expression level of glut2 and gck decreased to 0.312-fold and 0.093-fold, respectively. pck1 was upregulated by 2.533-fold in STZ-injected larvae. By tracking detection, we found the free-glucose level in STZ-injected larvae gradually approached the level of the solution injection control and the insulin content recovered at 6 days post-STZ injection (16 dpf). Consistent with the change of the glucose level, the regeneration rate of the caudal fin in the STZ-injected group decreased initially, but recovered and accelerated gradually finally at 8 days post-amputation (20 dpf). These results indicate the generation of a transient hyperglycemia model due to β-cell apoptosis caused by STZ, which is abated by the vigorous regeneration ability of β cells in zebrafish larvae.
ISSN:0920-1742
1573-5168
DOI:10.1007/s10695-020-00769-w