Imaging technology developed at Garvan Institute shows that bone-resorbing osteoclasts gather in distinct pockets, leading to new insights for osteoporosis and cancer treatment.
Image of cells contained in a bone tissue. Image credit: Garvan Institute
Bone may seem like a hard, lifeless structure. Still, the cells living within have been imaged in unprecedented detail, thanks to an innovative imaging method developed at the Garvan Institute of Medical Research.
The new method lets researchers study cells inside the bones of mice, to visualise not just isolated sections, but the entire length of a bone. With a new level of visual detail, the researchers discovered that osteoclasts, cells that break down bone tissue, are more active in some parts of the bone than others.
This knowledge could be used to develop new treatments for osteoporosis, and for dormant cancer cells, which can stay hidden in bone for years until osteoclasts reactivate them.
“Our method has given us an unprecedented window into how cells go about breaking down bone, giving us a new way to investigate osteoporosis and cancer relapse in bone,” says Professor Tri Phan, Head of the Intravital Microscopy Lab and Gene Expression (IMAGE) Lab, immunologist at St Vincent’s Hospital Sydney, Co-Director of the Precision Immunology Program at Garvan and senior author of the paper, published in Nature Protocols.
“We can finally image processes inside bone that we thought were happening, but which were until now beyond the limits of conventional microscopy techniques. We are only beginning to understand the implications of this exciting technology.”
Picture of the bones in a human hand (from an authentic human skeleton). Image credit: Raul654 via Wikimedia, CC-BY-SA-3.0
Giving disease-causing cells no place to hide
Osteoclasts are crucial to the normal maintenance and repair processes of bone, but when they are overly active, they can cause excessive breakdown, known as osteoporosis.
“The inside of living bone is a ‘dark space’ that is difficult to study, because of its hard, mineralised structure,” says co-first author Dr Nayan Deger Bhattacharyya, post-doctoral researcher in the IMAGE Lab. “In order to understand diseases such as osteoporosis and cancer recurrence, we’ve needed to develop the technology to look inside bone tissue.”
The new technique developed at Garvan’s ACRF INCITe Centre can image other dynamic cellular processes until now hidden in bone.
“Our new imaging method is minimally invasive and lets us map out localised populations of cells along the length of an entire bone in our mouse models, instead of just in small sections,” says co-first author Wunna Kyaw, PhD student in the IMAGE Lab.
The researchers tracked down distinct pockets of bone resorption activity as the cells ‘morph’ between actively resorbing osteoclasts and an intermediate cell state called osteomorphs, in real time.
Osteoporosis in bones. Image credit: Scientific Animations, CC BY-SA 4.0
“We suspect these osteomorphs are dangerous as they can accumulate while osteoporosis treatment is administered but can rapidly reform activated osteoclasts to supercharge bone breakdown as soon as treatment is stopped.”
“This would explain an observation in the clinic, that many osteoporosis patients taking the medication denosumab, which blocks osteoclasts from resorbing bone, experience rebound vertebral fractures after they stop using the drug. We will use our imaging method to study how this withdrawal effect could be prevented,” says co-author Professor Peter Croucher, Head of the Bone Biology Lab at Garvan.
The researchers say their method could also be used to investigate cancer cells that can migrate to bone during cancer treatment and lie dormant there for years, only to be reactivated by osteoclasts breaking down the bone tissue surrounding them.
“Being able to see cells and molecules interact in the bone – and one day target them – could be a critical new tool for bone-related diseases,” says Professor Phan.
Source: Garvan Institute