Stretching inhibits tumor growth in MMTV-PYMT via a direct mechanical effect
Data files
Jan 29, 2026 version files 62.87 KB
-
Berrueta_et_al__qPCR_data_from_Orthotopic_active_stretch_Master_file__Batch_16-18___062323.csv
2.14 KB
-
Berrueta_et_al__qPCR_Orthotopic_passive_stretch_Master_file_Batch___071823.csv
2.58 KB
-
Berrueta_et_al__Spheroids_Crown_area_at_day_3.csv
4.48 KB
-
Berrueta_et_al__Spheroids_distance_Travelled_at_day_3_all_data.xlsx
28.47 KB
-
Berrueta_et_al__Transgenic__active_stretch__master_file.csv
4.56 KB
-
Berrueta_et_al__Transgenics_passive_stretch_Master_file_52423.csv
1.92 KB
-
Berrueta_et_al_Orthotopic_active_stretch_Master_file__72623.csv
6.04 KB
-
Berrueta_et_al_Orthotopic_model_Passive_stretch_master_file_61223.csv
2.43 KB
-
Berrueta_et_al_tumors_collagen_signature_Data__092624.csv
396 B
-
Berrueta_et_el___Spheroids_single_cell_migration_at_day_3.csv
2.99 KB
-
Passive_stretching_amplitude_ultrasound_data.csv
1.50 KB
-
README.md
5.38 KB
Abstract
Background: Tumor-associated architecture and emerging mechanical properties (forces, pressure, tension, stiffness) affect the growth and invasiveness of cancer cells. Collagen fibers aligned perpendicular to the boundaries of tumors promote local tumor invasiveness in mouse mammary tumor models and are associated with a poor prognosis in human breast cancer. Our previous study revealed that daily gentle stretching (~25% strain) for 10 min reduced the growth of P53/PTEN-/- orthotopic mouse mammary tumors by 50%.
Results: In this study, we further investigated the mechanism of stretching in a more aggressive MMTV-PYMT (mammary tumor virus-polyomavirus middle T antigen) tumor model in vivo and in vitro and analyzed its impact on collagen reorganization at both the tumor-stromal interface and the tumor microenvironment composition at single cell level. Stretching reduced the average tumor size by 30–50% in orthotopic (Active and Passive Stretch) and transgenic (Passive Stretch) models. In the orthotopic model, the ratio of parallel vs. perpendicular collagen fibers relative to the tumor boundary, was greater in the Stretch group compared with the No Stretch group. Finally, stretching reduced the cell migration of collagen-embedded tumor spheroids in vitro.
Conclusions: These results show that short-duration, moderate-amplitude stretching reduces tumor growth in several different animal models. We also provide evidence that this beneficial effect may be a direct mechanical effect on local matrix properties and tumor cell invasiveness.
Dataset DOI: 10.5061/dryad.1rn8pk13r
Description of the data and file structure
Berrueta_et_al__qPCR_Orthotopic_passive_stretch_Master_file_Batch___071823.csv
The data include 13 columns: column A is Animal Identification (ID); column B is batch number, column C; is condition: 1=Stretch, 0= No stretch; column D is relative gene expression for collagen 1a1 (Col1a1); column E is relative gene expression for Collagen 5a2 (Col5a2); column F is relative gene expression for Collagen 6a2 (Col6a2); Column G is relative gene expression for Actin Alpha 2, Smooth Muscle (a-SMA), Column H is relative gene expression for Transforming Growth Factor Beta (TGF-b); Column I is relative gene expression for connexin-43; Column J is relative gene expression for Piezo; Column K is relative gene expression for Discoidin Domain Receptor 1 (Ddr1); Column L is relative gene expression for Discoidin Domain Receptor 2 (Ddr2); Column M is relative gene expression for Lysyl Oxidase Like 3 (Loxl3)
Berrueta_et_al__qPCR_data_from_Orthotopic_active_stretch_Master_file__Batch_16-18___062323.csv
The data include 12 columns: column A is Animal Identification (ID); column B is batch number; column C is condition: 1=Stretch, 0= No stretch; column D is relative gene expression for collagen 1a1 (Col1a1); column E is relative gene expression for Collagen 5a2 (Col5a2); column F is relative gene expression for Collagen 6a2 (Col6a2); Column G is relative gene expression for Actin Alpha 2, Smooth Muscle (a-SMA), Column H is relative gene expression for Transforming Growth Factor Beta (TGF-b); Column I is relative gene expression for connexin-43; Column J is relative gene expression for Piezo; Column K is relative gene expression for Discoidin Domain Receptor 1 (Ddr1); Column L is relative gene expression for Discoidin Domain Receptor 2 (Ddr2)
Passive_stretching_amplitude_ultrasound_data.csv
The data include 3 columns: column A is Animal Identification (ID); column B is the amplitude or body displacement during passive stretch, expressed in percentage; column C is the tumor volume by ultrasound expressed in mm^3
Berrueta_et_al__Transgenic__active_stretch__master_file.csv
The data include 8 columns: column A is Animal Identification (ID); column B is batch number; column C is week number; column D is condition: 1=Stretch, 0= No stretch; column E is animal mass in grams (g); column F is the tumor volume measured by ultrasound and expressed in mm^3; column g is tumor weight in grams (g); column H is the number of lung metastasis
Berrueta_et_al__Transgenics_passive_stretch_Master_file_52423.csv
The data include 6 columns: column A is Animal Identification (ID); column B is batch number; column C is week number; column D is condition: 1=Stretch, 0= No stretch; column E is the tumor volume measured by ultrasound and expressed in mm^3; column F is tumor weight in grams (g)
Berrueta_et_al__Spheroids_distance_Travelled_at_day_3_all_data.xlsx
The data include 5 columns: column A is the experiment number; column B is group identification, NS=No stretch, S= Stretch; column C is gel number; column D is condition: 0=No stretch, 1= Stretch; column E is distance travelled at day 3
Berrueta_et_al__Spheroids_Crown_area_at_day_3.csv
The data include 5 columns: column A is the experiment number; column B is group identification, NS=No stretch, S= Stretch; column C is gel number; column D is condition: 0=No stretch, 1= Stretch; column E is Crown area or migration area surrounding the spheroid at day 3
Berrueta_et_al_tumors_collagen_signature_Data__092624.csv
The data include 4 columns: column A is Animal Identification (ID); column B is animal code for condition: 0=No stretch, 1= Stretch; column C is tumor associated collagen signature 2 (TACS2) expressed in percentage; column D is tumor associated collagen signature 3 (TACS3) expressed in percentage
Berrueta_et_al_Orthotopic_active_stretch_Master_file__72623.csv
The data include 8 columns: column A is Animal Identification (ID); column B is batch number; column C is week number; column D is condition: 1=Stretch, 0= No stretch; column E is animal weight or mass in grams (g); column F is the tumor volume measured by ultrasound and expressed in mm^3; column F is tumor weight in grams (g); column G is tumor volume measured by caliper (using the formula: 3.14LW*W and averaging left and right tumors); column H is number of lung metastasis
Berrueta_et_al___Spheroids_single_cell_migration_at_day_3.csv
The data include 5 columns: column A is the experiment number; column B is group identification, NS=No stretch, S= Stretch; column C is gel number; column D is condition: 0=No stretch, 1= Stretch; column E is migration measured per single cell
Berrueta_et_al_Orthotopic_model_Passive_stretch_master_file_61223.csv
The data include 7 columns: column A is Animal Identification (ID); column B is batch number; column C is week number; column D is condition: 1=Stretch, 0= No stretch; column E is the tumor volume measured by ultrasound and expressed in mm^3; column F is tumor volume measured by caliper (using the formula: 3.14LW*W and averaging left and right tumors); column G is tumor weight in grams (g)
Berrueta et al tumors collagen signature Data 092624: data was collected from images taken by confocal second harmonic generation microscopy and analyzed using the CurveAlign sofware
Berrueta et al Orthotopic active stretch Master file 72623: data was collected by weekly measurements of the tumor using caliper and 3D ultrasound and procceced with the VevoLab sofware
Berrueta et al Orthotopic model Passive stretch master file 61223: data was collected by weekly measurements of the tumor using caliper and 3D ultrasound and procceced with the VevoLab sofware
Berrueta et al qPCR data from Orthotopic active stretch Master file _Batch 16-18 062323: data was collected by homogenizing the tumors after euthanasia, then extracting RNA and running qPCR for gene expression
Berrueta et al qPCR Orthotopic passive stretch Master file Batch 071823: data was collected by homogenizing the tumors after euthanasia, then extracting RNA and running qPCR for gene expression
Berrueta et al Transgenics passive stretch Master file: data was collected weekly using 3D ultrasound and analyzed with the VevoLab software
Berrueta et al Transgenics active stretch Master file: data was collected weekly using 3D ultrasound and analyzed with the VevoLab software
Berrueta et al _Spheroids Crown area at day 3: data was obtained measuring the area of cell migration surrounding each spheroid using the ImageJ software, creating a binary image by applying thresholding through: Image/Adjust/Threshold
Berrueta et al, Spheroids distance Travelled at day 3_all data: Data was obtained from photograph taken from the spheroids and then measuring the distance between the spheroid boundery and the location of the cell using ImajeJ software The calculation of the maximum distance traveled by migratory cells involved measuring the distance from the edge of the spheroid to the furthest point reached by the migratory cells (the sixteen cells that were at the furthest distance from the edge of the spheroid were measured in all spheroids)
Berrueta et el, Spheroids single cell migration at day 3 This data was obtained by counting the total number of individual cells that migrated away from the spheroid