Abstract

Purpose: Computational modeling of biological networks permits comprehensive analysis of cells and tissues to define molecular phenotypes and novel hypotheses. We recently presented ANIMO (Analysis of Networks with Interactive Modeling), an intuitive software tool for modeling molecular networks for use by biologists. We used ANIMO to generate a computational model of articular cartilage, ECHO. Over 1.5 million people in the Netherlands suffer from osteoarthritis (OA) in one or more joints. OA is a painful, disabling disease and currently cannot be cured. In a subset of OA patients, joint cartilage is replaced by bone via endochondral ossification. This is a natural process in growing long bones, where transient growth plate cartilage is replaced by bone. In contrast, healthy joint cartilage is permanent as it is protected against bone formation. Stable joint cartilage is under control of master transcription factor SOX9, whereas bone formation is controlled by RUNX2. The processes that regulate the switch between a SOX9+ state and a RUNX+ state are poorly understood, which greatly hampers the development of successful therapies.

Methods: Based on a large-scale literature study and our own experiments, we recently developed ECHO (Executable Chondrocyte), a computational model of the key processes that regulate expression and activity of SOX9 and RUNX2. Simulations in ECHO were performed to investigate the robustness of the chondrocyte network.To validate ECHO predictions, we used FRAP to measure mobility of SOX9 and RUNX2, which we have shown to be a faithful readout of their activity.Primary chondrocytes of 2 OA donors were tested at passage 2 after isolation. In these donors we observed little interdonor variation in SOX9 mobility. Using lipofectamine LTX we obtained 40-70% transfection efficiencies in primary human chondrocytes even at low passages.Results:In its unperturbed form, ECHO displays two stable states in which activities of SOX9 and RUNX2 are mutually exclusive. We tested the hypothesis that addition of WNT (performed with a few mouse clicks) will change permanent into transient cartilage by inducing hypertrophy. Indeed, when we add WNT, a known regulator of bone formation, the permanent or SOX9+ state changes to a transient or RUNX2+ state. However, it is known that healthy articular cartilage is resistant to hypertrophic differentiation. Our group has previously found that this was probably due to the secretion of DKK1, FRZB and GREM1. We therefore added nodes to ECHO representing DKK1, FRZB and GREM1 (figure 1). GREM1 and DKK1 are able to stabilize the permanent cartilage or SOX9+ state even after addition of WNT to ECHO. We observed that in our model activation of WNT leads to a switch from a SOX9+ state to a RUNX2+ state. To prove that WNT/β-catenin signaling can directly regulate SOX9 function, we investigated the response of SOX9 mobility to WNT3A in live primary chondrocytes. Addition of WNT3A to human chondrocytes transfected with SOX9-GFP resulted in a significant decrease of the immobile SOX9 fraction from 53% to 34% within 15 minutes after addition. A direct correlation between the elevated levels of β-catenin after WNT addition and the activity of SOX9 indicates that β-catenin can directly change the mobility by complex formation with SOX9.

Conclusions: Using ECHO we predicted the stimuli that prevents hypertrophic differentiation differentiation of articular cartilage, and tested this experimentally with FRAP using SOX9 and RUNX2 mobility as a read-out.
Original languageEnglish
Pages (from-to)S157-S157
Number of pages1
JournalOsteoarthritis and cartilage
Volume22
Issue numbersuppl.
DOIs
StatePublished - 24 Apr 2014
Event2014 OARSI World Congress on Osteoarthritis - Paris, France

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Chondrocytes
Cartilage
Bone
Osteoarthritis
beta Catenin
Articular Cartilage
Osteogenesis
Switches
Bone and Bones
Transcription factors
Molecular modeling
Chemical activation
Display devices
Tissue
Experiments
SOX9 Transcription Factor
Growth Plate
Bone Development
Netherlands
Hypertrophy

Keywords

  • IR-91615
  • METIS-305291

Cite this

@article{f7914c5ea6344871b222cc19a04aeb14,
title = "An echo in biology: validating the executable chondrocyte",
abstract = "Purpose: Computational modeling of biological networks permits comprehensive analysis of cells and tissues to define molecular phenotypes and novel hypotheses. We recently presented ANIMO (Analysis of Networks with Interactive Modeling), an intuitive software tool for modeling molecular networks for use by biologists. We used ANIMO to generate a computational model of articular cartilage, ECHO. Over 1.5 million people in the Netherlands suffer from osteoarthritis (OA) in one or more joints. OA is a painful, disabling disease and currently cannot be cured. In a subset of OA patients, joint cartilage is replaced by bone via endochondral ossification. This is a natural process in growing long bones, where transient growth plate cartilage is replaced by bone. In contrast, healthy joint cartilage is permanent as it is protected against bone formation. Stable joint cartilage is under control of master transcription factor SOX9, whereas bone formation is controlled by RUNX2. The processes that regulate the switch between a SOX9+ state and a RUNX+ state are poorly understood, which greatly hampers the development of successful therapies.Methods: Based on a large-scale literature study and our own experiments, we recently developed ECHO (Executable Chondrocyte), a computational model of the key processes that regulate expression and activity of SOX9 and RUNX2. Simulations in ECHO were performed to investigate the robustness of the chondrocyte network.To validate ECHO predictions, we used FRAP to measure mobility of SOX9 and RUNX2, which we have shown to be a faithful readout of their activity.Primary chondrocytes of 2 OA donors were tested at passage 2 after isolation. In these donors we observed little interdonor variation in SOX9 mobility. Using lipofectamine LTX we obtained 40-70% transfection efficiencies in primary human chondrocytes even at low passages.Results:In its unperturbed form, ECHO displays two stable states in which activities of SOX9 and RUNX2 are mutually exclusive. We tested the hypothesis that addition of WNT (performed with a few mouse clicks) will change permanent into transient cartilage by inducing hypertrophy. Indeed, when we add WNT, a known regulator of bone formation, the permanent or SOX9+ state changes to a transient or RUNX2+ state. However, it is known that healthy articular cartilage is resistant to hypertrophic differentiation. Our group has previously found that this was probably due to the secretion of DKK1, FRZB and GREM1. We therefore added nodes to ECHO representing DKK1, FRZB and GREM1 (figure 1). GREM1 and DKK1 are able to stabilize the permanent cartilage or SOX9+ state even after addition of WNT to ECHO. We observed that in our model activation of WNT leads to a switch from a SOX9+ state to a RUNX2+ state. To prove that WNT/β-catenin signaling can directly regulate SOX9 function, we investigated the response of SOX9 mobility to WNT3A in live primary chondrocytes. Addition of WNT3A to human chondrocytes transfected with SOX9-GFP resulted in a significant decrease of the immobile SOX9 fraction from 53% to 34% within 15 minutes after addition. A direct correlation between the elevated levels of β-catenin after WNT addition and the activity of SOX9 indicates that β-catenin can directly change the mobility by complex formation with SOX9.Conclusions: Using ECHO we predicted the stimuli that prevents hypertrophic differentiation differentiation of articular cartilage, and tested this experimentally with FRAP using SOX9 and RUNX2 mobility as a read-out.",
keywords = "IR-91615, METIS-305291",
author = "Jetse Scholma and Stefano Schivo and Karperien, {Hermanus Bernardus Johannes} and Romanus Langerak and {van de Pol}, {Jan Cornelis} and Post, {Janine Nicole}",
note = "Abstracts from the 2014 World Congress",
year = "2014",
month = "4",
doi = "10.1016/j.joca.2014.02.291",
volume = "22",
pages = "S157--S157",
journal = "Osteoarthritis and cartilage",
issn = "1063-4584",
publisher = "W.B. Saunders Ltd",
number = "suppl.",

}

TY - JOUR

T1 - An echo in biology: validating the executable chondrocyte

AU - Scholma,Jetse

AU - Schivo,Stefano

AU - Karperien,Hermanus Bernardus Johannes

AU - Langerak,Romanus

AU - van de Pol,Jan Cornelis

AU - Post,Janine Nicole

N1 - Abstracts from the 2014 World Congress

PY - 2014/4/24

Y1 - 2014/4/24

N2 - Purpose: Computational modeling of biological networks permits comprehensive analysis of cells and tissues to define molecular phenotypes and novel hypotheses. We recently presented ANIMO (Analysis of Networks with Interactive Modeling), an intuitive software tool for modeling molecular networks for use by biologists. We used ANIMO to generate a computational model of articular cartilage, ECHO. Over 1.5 million people in the Netherlands suffer from osteoarthritis (OA) in one or more joints. OA is a painful, disabling disease and currently cannot be cured. In a subset of OA patients, joint cartilage is replaced by bone via endochondral ossification. This is a natural process in growing long bones, where transient growth plate cartilage is replaced by bone. In contrast, healthy joint cartilage is permanent as it is protected against bone formation. Stable joint cartilage is under control of master transcription factor SOX9, whereas bone formation is controlled by RUNX2. The processes that regulate the switch between a SOX9+ state and a RUNX+ state are poorly understood, which greatly hampers the development of successful therapies.Methods: Based on a large-scale literature study and our own experiments, we recently developed ECHO (Executable Chondrocyte), a computational model of the key processes that regulate expression and activity of SOX9 and RUNX2. Simulations in ECHO were performed to investigate the robustness of the chondrocyte network.To validate ECHO predictions, we used FRAP to measure mobility of SOX9 and RUNX2, which we have shown to be a faithful readout of their activity.Primary chondrocytes of 2 OA donors were tested at passage 2 after isolation. In these donors we observed little interdonor variation in SOX9 mobility. Using lipofectamine LTX we obtained 40-70% transfection efficiencies in primary human chondrocytes even at low passages.Results:In its unperturbed form, ECHO displays two stable states in which activities of SOX9 and RUNX2 are mutually exclusive. We tested the hypothesis that addition of WNT (performed with a few mouse clicks) will change permanent into transient cartilage by inducing hypertrophy. Indeed, when we add WNT, a known regulator of bone formation, the permanent or SOX9+ state changes to a transient or RUNX2+ state. However, it is known that healthy articular cartilage is resistant to hypertrophic differentiation. Our group has previously found that this was probably due to the secretion of DKK1, FRZB and GREM1. We therefore added nodes to ECHO representing DKK1, FRZB and GREM1 (figure 1). GREM1 and DKK1 are able to stabilize the permanent cartilage or SOX9+ state even after addition of WNT to ECHO. We observed that in our model activation of WNT leads to a switch from a SOX9+ state to a RUNX2+ state. To prove that WNT/β-catenin signaling can directly regulate SOX9 function, we investigated the response of SOX9 mobility to WNT3A in live primary chondrocytes. Addition of WNT3A to human chondrocytes transfected with SOX9-GFP resulted in a significant decrease of the immobile SOX9 fraction from 53% to 34% within 15 minutes after addition. A direct correlation between the elevated levels of β-catenin after WNT addition and the activity of SOX9 indicates that β-catenin can directly change the mobility by complex formation with SOX9.Conclusions: Using ECHO we predicted the stimuli that prevents hypertrophic differentiation differentiation of articular cartilage, and tested this experimentally with FRAP using SOX9 and RUNX2 mobility as a read-out.

AB - Purpose: Computational modeling of biological networks permits comprehensive analysis of cells and tissues to define molecular phenotypes and novel hypotheses. We recently presented ANIMO (Analysis of Networks with Interactive Modeling), an intuitive software tool for modeling molecular networks for use by biologists. We used ANIMO to generate a computational model of articular cartilage, ECHO. Over 1.5 million people in the Netherlands suffer from osteoarthritis (OA) in one or more joints. OA is a painful, disabling disease and currently cannot be cured. In a subset of OA patients, joint cartilage is replaced by bone via endochondral ossification. This is a natural process in growing long bones, where transient growth plate cartilage is replaced by bone. In contrast, healthy joint cartilage is permanent as it is protected against bone formation. Stable joint cartilage is under control of master transcription factor SOX9, whereas bone formation is controlled by RUNX2. The processes that regulate the switch between a SOX9+ state and a RUNX+ state are poorly understood, which greatly hampers the development of successful therapies.Methods: Based on a large-scale literature study and our own experiments, we recently developed ECHO (Executable Chondrocyte), a computational model of the key processes that regulate expression and activity of SOX9 and RUNX2. Simulations in ECHO were performed to investigate the robustness of the chondrocyte network.To validate ECHO predictions, we used FRAP to measure mobility of SOX9 and RUNX2, which we have shown to be a faithful readout of their activity.Primary chondrocytes of 2 OA donors were tested at passage 2 after isolation. In these donors we observed little interdonor variation in SOX9 mobility. Using lipofectamine LTX we obtained 40-70% transfection efficiencies in primary human chondrocytes even at low passages.Results:In its unperturbed form, ECHO displays two stable states in which activities of SOX9 and RUNX2 are mutually exclusive. We tested the hypothesis that addition of WNT (performed with a few mouse clicks) will change permanent into transient cartilage by inducing hypertrophy. Indeed, when we add WNT, a known regulator of bone formation, the permanent or SOX9+ state changes to a transient or RUNX2+ state. However, it is known that healthy articular cartilage is resistant to hypertrophic differentiation. Our group has previously found that this was probably due to the secretion of DKK1, FRZB and GREM1. We therefore added nodes to ECHO representing DKK1, FRZB and GREM1 (figure 1). GREM1 and DKK1 are able to stabilize the permanent cartilage or SOX9+ state even after addition of WNT to ECHO. We observed that in our model activation of WNT leads to a switch from a SOX9+ state to a RUNX2+ state. To prove that WNT/β-catenin signaling can directly regulate SOX9 function, we investigated the response of SOX9 mobility to WNT3A in live primary chondrocytes. Addition of WNT3A to human chondrocytes transfected with SOX9-GFP resulted in a significant decrease of the immobile SOX9 fraction from 53% to 34% within 15 minutes after addition. A direct correlation between the elevated levels of β-catenin after WNT addition and the activity of SOX9 indicates that β-catenin can directly change the mobility by complex formation with SOX9.Conclusions: Using ECHO we predicted the stimuli that prevents hypertrophic differentiation differentiation of articular cartilage, and tested this experimentally with FRAP using SOX9 and RUNX2 mobility as a read-out.

KW - IR-91615

KW - METIS-305291

U2 - 10.1016/j.joca.2014.02.291

DO - 10.1016/j.joca.2014.02.291

M3 - Article

VL - 22

SP - S157-S157

JO - Osteoarthritis and cartilage

T2 - Osteoarthritis and cartilage

JF - Osteoarthritis and cartilage

SN - 1063-4584

IS - suppl.

ER -