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Lipopolysaccharide Potentiates the Effect of Hepatocyte Growth Factor upon Replication in Lung, Thyroid, Spleen, and Colon in Rats in Vivo  Cuihua Gao,

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Presentation on theme: "Lipopolysaccharide Potentiates the Effect of Hepatocyte Growth Factor upon Replication in Lung, Thyroid, Spleen, and Colon in Rats in Vivo  Cuihua Gao,"— Presentation transcript:

1 Lipopolysaccharide Potentiates the Effect of Hepatocyte Growth Factor upon Replication in Lung, Thyroid, Spleen, and Colon in Rats in Vivo  Cuihua Gao, Susan Kennedy, Katherine Parker Ponder  Molecular Therapy  Volume 3, Issue 4, Pages (April 2001) DOI: /mthe Copyright © 2001 American Society for Gene Therapy Terms and Conditions

2 FIG. 1 Schematic diagram of the injection regimen for HGF, LPS, or both, and the method for BrdU labeling. (A) Injection regimen. For rats that received HGF alone, HGF was injected iv every 3 h at 1.25 mg/kg/dose beginning at time = 0 h, and was continued every 3 h for a total of 8 doses. The cumulative dose of HGF was 10 mg/kg, and PBS was injected at –1 h. For rats that received LPS alone, LPS was injected ip at –1 h and PBS was injected at other times. For rats that received HGF and LPS, LPS was injected at –1 h, and HGF was injected every 3 h at 0 to 21 h. (B) BrdU labeling protocol. For determination of the percentage of cells that replicated between 24 and 33 h, 100 mg/kg of BrdU was injected at 24, 27, and 30 h, and the animal was sacrificed at 33 h. Frozen sections were analyzed for the percentage of replicating cells with anti-BrdU immunostaining. A similar strategy was used to determine the percentage of cells that replicated at 33–42 h or 42–51 h after the first dose of HGF. Molecular Therapy 2001 3, DOI: ( /mthe ) Copyright © 2001 American Society for Gene Therapy Terms and Conditions

3 FIG. 2 (A–D) Examples of replication in the alveoli. Rats received no treatment (A) or were treated with HGF alone (B), LPS alone (C), or both HGF and LPS (D) according to the regimen shown in Fig. 1. The labeling index was determined at 33 to 42 h after time 0, as detailed in Fig. 1. Frozen sections underwent anti-BrdU immunostaining with a development procedure that results in a brown shading and were stained with H & E. The black arrows identify nuclei of cells that had recently replicated, while cells with blue nuclei had not replicated. All photographs were at a 60× original magnification. (E) Quantitation of the BrdU labeling index in the alveoli. The average ± SEM of the BrdU labeling index (LI) in the alveolar cells for the indicated number of animals is shown. Values that were significantly different from those in normal rats using Student's t test are identified with asterisks; the criteria for significance are detailed under Materials and Methods. Values in normal rats are shown as the 0-h data point. Molecular Therapy 2001 3, DOI: ( /mthe ) Copyright © 2001 American Society for Gene Therapy Terms and Conditions

4 FIG. 3 (A–D) Examples of replication in the bronchial epithelium. Rats were treated as noted in the legend to Fig. 2, and anti-BrdU followed by H & E staining was performed to determine the percentage of replicating cells in the bronchial epithelium. Rats received no treatment (A) or were treated with HGF alone (B), LPS alone (C), or both HGF and LPS (D). All photographs were at a 60× original magnification. The black arrows identify BrdU-labeled bronchial epithelial cell. The lumen of the bronchus is at the top for all panels. (E) Quantitation of the BrdU labeling index in bronchial epithelial cells. Molecular Therapy 2001 3, DOI: ( /mthe ) Copyright © 2001 American Society for Gene Therapy Terms and Conditions

5 FIG. 4 (A-D) Examples of replication in the proximal tubular cells of the kidney. Rats were treated as noted in the legend to Fig. 2, and anti-BrdU followed by H & E staining was performed to determine the percentage of replicating cells in the proximal tubular cells of the kidney at 33 to 42 h after time 0. Rats received no treatment (A) or were treated with HGF alone (B), LPS alone (C), or both HGF and LPS (D). All photographs were at a 60× original magnification. BrdU-labeled proximal tubular cells are identified with a black arrow. Red arrows identify the lumen of the tubule. (E) Quantitation of the BrdU labeling index in proximal tubular cells of the kidney. Molecular Therapy 2001 3, DOI: ( /mthe ) Copyright © 2001 American Society for Gene Therapy Terms and Conditions

6 FIG. 5 (A-D) Examples of replication in epithelial cells of the colon. Rats were treated as noted in the legend to Fig. 2, and anti-BrdU followed by H & E staining was performed to determine the percentage of replicating epithelial cells of the colon at 33 to 42 h after time 0. Rats received no treatment (A) or were treated with HGF alone (B), LPS alone (C), or both HGF and LPS (D). All photographs were at a 30× original magnification. BrdU-labeled colonic epithelial cells are identified with a black arrow. Red arrows identify the lumen of the colon. (E) Quantitation of the BrdU labeling index in colonic epithelial cells. (F) Quantitation of the height of the crypts of the colon. Crypt heights were measured from the base of the crypt to the lumen of the colon and plotted as the average ± SEM in micrometers. There were no significant differences between samples from normal rats and those from any of the experimental groups. Molecular Therapy 2001 3, DOI: ( /mthe ) Copyright © 2001 American Society for Gene Therapy Terms and Conditions

7 FIG. 6 (A–D) Examples of replication in the epithelial cells of the thyroid. Rats were treated as noted in the legend to Fig. 2, and anti-BrdU followed by H & E staining was performed to determine the percentage of replicating cells in the epithelial cells of the thyroid at 33 to 42 h after time 0. Rats received no treatment (A) or were treated with HGF alone (B), LPS alone (C), or both HGF and LPS (D). All photographs were at a 60× original magnification. BrdU-labeled proximal tubular cells are identified with a black arrow. Red arrows identify the lumen of the tubule. (E) Quantitation of the BrdU labeling index in epithelial cells of the thyroid. Molecular Therapy 2001 3, DOI: ( /mthe ) Copyright © 2001 American Society for Gene Therapy Terms and Conditions

8 FIG. 7 (A, C, E, and G) Examples of replication of cells in the spleen. Rats were treated as noted in the legend to Fig. 2. Anti-BrdU immunostaining followed by a light eosin counterstain (A, C, E, and G) was performed to determine the percentage of replicating cells in the spleen at 33 to 42 h after time 0. The BrdU-labeled cells appear as small brown dots. An adjacent section was stained with H & E to help to identify the different regions of the spleen. The red arrows indicate the outer edge of the white pulp, which is located in the center of all panels. The blue arrow identifies a region of red pulp. Rats received no treatment (A and B) or were treated with HGF alone (C and D), LPS alone (E and F), or both HGF and LPS (G and H). All photographs were at a 10× original magnification. (I) Quantitation of the BrdU labeling index in the white pulp. (J) Quantitation of the BrdU labeling index in the red pulp. Molecular Therapy 2001 3, DOI: ( /mthe ) Copyright © 2001 American Society for Gene Therapy Terms and Conditions

9 FIG. 8 (A–D) Examples of replication in the thymus. Rats were treated as noted in the legend to Fig. 2, and anti-BrdU followed by eosin staining was performed to determine the percentage of replicating cells in the thymus at 33 to 42 h after time 0. BrdU-labeled cells appear as small brown dots that are identified with a black arrow and are more prevalent in the cortex of normal rats. The outer edges of the medulla, which is located in the center of each panel, are identified with red arrows. The edge of the lobule is identified with blue arrows. Rats received no treatment (A) or were treated with HGF alone (B), LPS alone (C), or both HGF and LPS (D). All photographs were at a 10× original magnification. (E) Quantitation of the BrdU labeling index in cortex of the thymus. (F) Quantitation of the BrdU labeling index in the medulla of the thymus. Molecular Therapy 2001 3, DOI: ( /mthe ) Copyright © 2001 American Society for Gene Therapy Terms and Conditions

10 FIG. 9 The effect of LPS upon c-met protein levels. Extracts from thyroid, spleen, or large intestine (Large int.) were harvested from normal rats or at the indicated times after treatment with 5 mg/kg of LPS. Immunoblot was performed on 50 to 100 μg of protein after electrophoresis on a reducing SDS-PAGE using an anti-c-met antibody. The position of the 145-kDa c-met protein is indicated at the right. Molecular Therapy 2001 3, DOI: ( /mthe ) Copyright © 2001 American Society for Gene Therapy Terms and Conditions

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