Mechanoregulation of gene expression in fibroblasts
http://www.sciencedirect.com/science?_ob=MImg&_imagekey=B6T39-4MY6G9W-1-7&_cdi=4941&_user=4420&_orig=search&_coverDate=04%2F15%2F2007&_sk=996089998&view=c&wchp=dGLbVtb-zSkzk&md5=62474072cb124b85f7f4b650feeedb2d&ie=/sdarticle.pdf
James H.-C. Wanga, , , Bhavani P. Thampattya, Jeen-Shang Linb and Hee-Jeong Imc aMechanoBiology Laboratory, Departments of Orthopaedic Surgery, Bioengineering, Mechanical Engineering, and Physical Medicine and Rehabilitation, University of Pittsburgh, 210 Lothrop St., BST, E1640, Pittsburgh, PA 15213, United StatesbDepartment of Civil and Environmental Engineering, School of Engineering, University of Pittsburgh, United StatescDepartments of Biochemistry and Internal Medicine, Rush University Medical Center, Cohn Research BD 558, 1735 W. Harrison, Chicago, IL 60612, United States
Intro: Mechanical loads placed on connective tissues alter gene expression in fibroblasts through mechanotransduction mechanisms by which cells convert mechanical signals into cellular biological events, such as gene expression of extracellular matrix components (e.g., collagen). This mechanical regulation of ECM gene expression affords maintenance of connective tissue homeostasis. However, mechanical loads can also interfere with homeostatic cellular gene expression and consequently cause the pathogenesis of connective tissue diseases such as tendinopathy and osteoarthritis. Therefore, the regulation of gene expression by mechanical loads is closely related to connective tissue physiology and pathology. This paper reviews the effects of various mechanical loading conditions on gene regulation in fibroblasts and discusses several mechanotransduction mechanisms. Future research directions in mechanoregulation of gene expression are also suggested.
used: Among many mechanoresponsive cells in our body, especially fibroblasts (collagen producing ECM cells) are studies for mechanotransduction resulting in gene regulation in this paper. Fibroblasts are also important for maintenance of most of the ECM components such as proteoglycans, growth factors, and cytokines.
experimental method: To mimic in vivo environment, tensile mechanical loading on fibroblasts in vitro is introduced using a substrate stretching method. This method is versatile; the loading parameters, including magnitude, frequency, and duration, are easy to control; and the mechanical properties of substrates as well as surface chemistry for cell attachment can be readily altered. The substrate deformation induced by substrate stretching is characterized by substrate surface strains.
To determine the effects of mechanical loading on fibroblasts, static or cyclic stretching is applied to a group of cells cultured on smooth, flexible elastic membranes (e.g.,silicone elastomers). And the mechanical force can be calculated by observating fluorescent beads attached on the sillicone substrate (for those in 116, we learned about this!:) ). In fact, 3D simulation of ECM by using collagen gels is more effective and accurate in terms of mimicking what's happening in vivo. Gene expression can be observed using PCR or RT-PCR.
Results: Induced collagen production, change in ECM components, growth factor, MMP secretion, TIMP (MMP inhibitor) expression, focal adhesion change, etc. (refer to Table 1.).
Discussion:
Gene regulation in fibroblasts depends on mechanical loading conditions: type (e.g., tension vs.compression), magnitude, frequency, and duration. The mechanoregulation of gene expression in fibroblasts also depends on the tissue location from which fibroblasts are derived, as well as ECM protein with which cells interact. To better understand how tissue homeostasis is maintained and how pathological conditions initiate and develop, it is necessary to study the effects of various mechanical loading conditions on fibroblasts. One challenging task in future research is to understand how a cell “decides” its response from “crosstalks” of many mechanotransduction signals, since mechanotransduction mechanisms do not function in isolation, but rather by an integrated network of various signaling pathways. Another particularly challenging task is to identify specific “force receptors,” for which specific proteins at the membrane–cytoskeletal interface(e.g., integrins and G proteins) are good candidates. Ultimately, additional research in mechanoregulation of gene expression in fibroblasts will aid in developing new therapeutic strategies and new approaches to engineering tissue constructs for improved repair and regeneration of connective tissues.
9 comments:
I suppose this is another example of how complex engineering a fully functional tissue really is. Perhaps this highlights the need to mimic entire cellular conditions, instead of having to simulate one particular process...we will ever discover these exact mechanisms?
Probably. But even if we figure out individual pathways (e.g. stretching causes certain gene expressions, compressing causes other gene expressions, etc.), these are always interconnected to each other in real life. These connections lead to other expressions as well: so a mere compression could cause many different gene expressions, and it is not easy to discover exact mechanisms. It is possible but hard. To summarize, because of signal "crosstalk" and "integrated network of various signaling pathways", it is hard. We could isolate individual signals using controls, but more research need to be done on this. Good point.
When mechanical loads are applied to connective tissue, is there an optimal stress that cells feel most comfortable at? For example, they start deviding more rapidly or secreting more collagen at certain stress.
Does mechanotransduction only occur in fibroblasts?
I will be happy to know more about force measurement using beads.
Yes, someone explain to me (simply) what all this force measurement with beads nonsense is. =p So, as you mentioned in the discussion section, force receptors such as integrins may come into play. Is it not possible that the mechanical forces on the cells cause different amounts of the integrins to be expressed? In that case, it seems to become increasingly difficult to pinpoint exactly how mechaniregulation occurs.
Thanks for the answer T.
To answer some of the questions posed by Ahra:
I am not so sure about "certain stress levels" cells prefer to be in: i am guessing that it might resemble a biphasic curve (just like migration!) which means too much stress could kill but too little doesn't "stimulate" cells either.
Mechanotransduction does not only occur in fibroblasts. As an extreme example, even plant cells respond to shear stress: RGD-Dependent Mechanotransduction of Suspension Cultured Taxus Cell in Response to Shear Stress
(Hong Gao, Yan-Wen Gong, and Ying-Jin Yuan*.) Osteocytes, for example, respond to shear stress and secrete osteopontin to deposit bone mass. This why body builders weigh more in general: more bone mass formation due to compression/shear stress from lifting weights.
Force measurement using beads: microbeads (fluorescent) are attached to the ultra-thin latex (or silicon) membrane. And pics are taken with cells on it. To actually convert microbead movement(from cell contraction), a complex system of force transducer, signal processor, and an inverted microscope are needed. For more info:http://ieeexplore.ieee.org/iel5/10375/32977/01545019.pdf?tp=&arnumber=1545019&isnumber=32977
-WHANWOOK ernest CHANG
hah, I never really did understand the method of measuring mechanical force through fluoresent beads. Looking at the 116 slides, was it the method using silicone rubber to visualize the forces? What I don't understand is wouldn't changing the substrate to measure the forces alter the cell's behavior in the first place?
I'm interested in cell mechanotransduction, so I looked forward to reading this article. I think the coolest part is that this dense review just touches the surface of the story. There are so many directions that one could go with this. You could use fluid shear stress to compare the results and be happy they're the same or happier that they're different, you could try doing single cell mechanical loads (such as AFM or micropipette aspiration) to see how the cells respond to more localized forces, or you could start trying to figure out what's going on inside the cell (cytoskeleton, integrins, etc.) to attempt to determine the mechanism of what's going on (which is so amazingly complex). This is on top of what they suggest for future work.
I wish this article wasn't so dense, it would have been much easier to go through =)
Thanks for the interest guys.
I am not really understanding your question Eric.
I guess when you change the substrate, you are not really tryin' to measure cells' contraction forces, but inducing a different set of actions rather.
-E
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