Mouse teeth providing new insights into tissue regeneration
UCSF News May 08, 2017
One of the enduring puzzles for stem cell researchers is how these remarkable cells know when itÂs time for them to expand in numbers and transform into mature, adult cells in order to renew injured or aging tissue.
The answer to this crucial decision–making process may lie in a most remarkable organ: the front tooth of the mouse.
Constantly growing incisors are the defining feature of all rodents, which rely on these sharp, chisel–like gnashers for burrowing and self–defense as well as gnawing food. Inside the jaw, a mouse's incisors look more like a walrusÂs tusks or the teeth of a saber–toothed tiger, with only the sharpened tips showing through the gums at the front of the mouth.
As the front of the tooth gets ground down, a pool of stem cells deep inside the jaw, at the very inner part of the tooth, is constantly building up the back of each incisor and pushing the growing tooth forward  a bit like the lead of a mechanical pencil.
ÂAs we grow older our teeth start to wear out, and in nature, once you donÂt have your teeth anymore, you die. As a result, mice and many other animals  from elephants to some primates  can grow their teeth continuously, said UC San FranciscoÂs Ophir Klein, MD, PhD, a professor of orofacial sciences in UCSFÂs School of Dentistry and of pediatrics in the School of Medicine. ÂOur labÂs objective is to learn the rules that let mouse incisors grow continuously to help us one day grow teeth in the lab, but also to help us identify general principles that could enable us to understand the processes of tissue renewal much more broadly."
In a new study, published online April 27, 2017, in the journal Cell Stem Cell, Jimmy Hu, PhD, a postdoctoral researcher in the Klein laboratory, has discovered that signals from the surrounding tissue are responsible for triggering these dental stem cells to leave their normal state of dormancy, hop on the conveyor belt of the growing tooth, and begin the process of transforming into mature tooth tissue.
ÂWe usually think of stem cells responding to chemical signals to start proliferating and differentiating, but here thereÂs an exciting interaction between the physical environment and the cells that can prompt them to meet the demands of the growing tooth, Hu said.
In their study, Hu and colleagues discovered that integrins, proteins that sit in cell membranes and link the internal skeleton of cells to the larger protein scaffolding of the surrounding tissue, trigger a newly described signaling cascade within the stem cells that causes them to begin rapidly multiplying  a process called Âproliferation. ItÂs not clear yet exactly what external signals are responsible for triggering the stem cells to proliferate, the authors say, but they propose that the cells could be detecting that they have moved into a region where the back of the tooth needs to actively produce more cells based on changes in local tissue stiffness or the physical forces pulling and pushing on the cells.
"Our data clearly show that as stem cells move into their designated proliferating space, they ramp up integrin production. These integrins allow the cells to interact with extracellular molecules and become triggered to expand in numbers before eventually producing a large pool of mature dental cells, Hu said.
Of additional interest to the researchers is the fact that both integrins and YAP  one of the molecules involved in the newly discovered integrin–triggered signaling cascade  have previously been implicated in the growth of certain types of tumors, which are thought to share some features of stem cell biology. This finding adds evidence to a growing sense among cancer researchers that interactions between cancer cells and the surrounding tissue may be a key step in triggering tumor growth.
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The answer to this crucial decision–making process may lie in a most remarkable organ: the front tooth of the mouse.
Constantly growing incisors are the defining feature of all rodents, which rely on these sharp, chisel–like gnashers for burrowing and self–defense as well as gnawing food. Inside the jaw, a mouse's incisors look more like a walrusÂs tusks or the teeth of a saber–toothed tiger, with only the sharpened tips showing through the gums at the front of the mouth.
As the front of the tooth gets ground down, a pool of stem cells deep inside the jaw, at the very inner part of the tooth, is constantly building up the back of each incisor and pushing the growing tooth forward  a bit like the lead of a mechanical pencil.
ÂAs we grow older our teeth start to wear out, and in nature, once you donÂt have your teeth anymore, you die. As a result, mice and many other animals  from elephants to some primates  can grow their teeth continuously, said UC San FranciscoÂs Ophir Klein, MD, PhD, a professor of orofacial sciences in UCSFÂs School of Dentistry and of pediatrics in the School of Medicine. ÂOur labÂs objective is to learn the rules that let mouse incisors grow continuously to help us one day grow teeth in the lab, but also to help us identify general principles that could enable us to understand the processes of tissue renewal much more broadly."
In a new study, published online April 27, 2017, in the journal Cell Stem Cell, Jimmy Hu, PhD, a postdoctoral researcher in the Klein laboratory, has discovered that signals from the surrounding tissue are responsible for triggering these dental stem cells to leave their normal state of dormancy, hop on the conveyor belt of the growing tooth, and begin the process of transforming into mature tooth tissue.
ÂWe usually think of stem cells responding to chemical signals to start proliferating and differentiating, but here thereÂs an exciting interaction between the physical environment and the cells that can prompt them to meet the demands of the growing tooth, Hu said.
In their study, Hu and colleagues discovered that integrins, proteins that sit in cell membranes and link the internal skeleton of cells to the larger protein scaffolding of the surrounding tissue, trigger a newly described signaling cascade within the stem cells that causes them to begin rapidly multiplying  a process called Âproliferation. ItÂs not clear yet exactly what external signals are responsible for triggering the stem cells to proliferate, the authors say, but they propose that the cells could be detecting that they have moved into a region where the back of the tooth needs to actively produce more cells based on changes in local tissue stiffness or the physical forces pulling and pushing on the cells.
"Our data clearly show that as stem cells move into their designated proliferating space, they ramp up integrin production. These integrins allow the cells to interact with extracellular molecules and become triggered to expand in numbers before eventually producing a large pool of mature dental cells, Hu said.
Of additional interest to the researchers is the fact that both integrins and YAP  one of the molecules involved in the newly discovered integrin–triggered signaling cascade  have previously been implicated in the growth of certain types of tumors, which are thought to share some features of stem cell biology. This finding adds evidence to a growing sense among cancer researchers that interactions between cancer cells and the surrounding tissue may be a key step in triggering tumor growth.
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