Chondrocytes in cartilage are embedded in a matrix containing a high concentration of proteoglycans and hence of fixed negative charges. Their extracellular ionic environment is thus different from that of most cells, with extracellular Na+ being 250-350 mM and extracellular osmolality 350-450 mOsm. When chondrocytes are isolated from the matrix and incubated in standard culture medium (DMEM; osmolality 250-280 mOsm), their extracellular environment changes sharply. We incubated isolated bovine articular chondrocytes and cartilage slices in DMEM whose osmolality was altered over the range 250-450 mOsm by Na+ or sucrose addition. 35S-sulphate and 3H-proline incorporation rates were at a maximum when the extracellular osmolality was 350-400 mOsm for both freshly isolated chondrocytes and for chondrocytes in cartilage. The incorporation rate per cell of isolated chondrocytes was only 10% that of chondrocytes in situ both 4 and 24 hours after isolation. For freshly isolated chondrocytes, the rate increased 30-50% in DMEM to which NaCl or sucrose had been added to increase osmolality. In chondrocytes incubated overnight in DMEM, the rate was greatest in DMEM of normal osmolality and fell from the maximum in proportion to the change in osmolality. The effects of sucrose addition on incorporation rates were similar but not identical to those of Na+ addition. Changes in cell volume might be linked to changes in synthesis rates since the cell volume of chondrocytes (measured by Coulter-counter) increased 30-40% when the cells were removed from their in situ environment into DMEM. Synthesis rates can thus be partly regulated by changes in extracellular osmolality, which in cartilage is controlled by proteoglycan concentration. This provides a mechanism by which the chondrocytes can rapidly respond to changes in extracellular matrix composition.
The volume of in situ chondrocytes within the superficial and mid-zones increased with cartilage degeneration. Cell swelling was greater than that expected from the increased hydration in OA, suggesting that an increase in chondrocyte volume might play a role in the changes to matrix metabolism occurring in OA.
Articular chondrocytes experience changes to matrix hydration during both physiological (static load) and pathophysiological (osteoarthrosis, OA) conditions. Such changes should alter chondrocytes' volume, which has been shown to modify matrix metabolism. However, the osmometric behaviour of chondrocytes is not well understood. Here, using confocal laser scanning microscopy (CLSM ), we have investigated the 'passive' osmotic responses of fluorescent-labelled chondrocytes within, and isolated from, the matrix. The volume-regulatory pathways normally activated by cell shrinkage/swelling, were blocked by bumetanidel REV5901, respectively. Chondrocytes in situ were broadly grouped in1.o superficial (SZ), mid (MZ) and deep (DZ) zones, and there was a significant increase in resting cell volume with depth into the cartilage. Variation in medium osmolarity (range 0-530 mOsm; corresponding to an extracellular osmolarity of -150 to -600 mOsm) caused a rapid and sustained change to in situ MZ chondrocytes' volume. Over the range 180-380 mOsm, the change to in situ or isolated chondrocytes' volume was similar. For MZ chondrocytes, ideal osmometric (Boyle-van't HofF) behaviour was apparent over the extracellular osmolarity range of -250 to -600 niOsm. Chondrocytes within the SZ appeared to be more sensitive to reduced osmolarity, swelling more for a given reduction in osmolarity, than M Z or D Z chondrocytes. These data show that over wide variations in osmolarity, articular chondrocytes in situ were osmotically sensitive, and for MZ chondrocytes behaved as perfect osmometers with the extracellular matrix (ECM) not restraining cell volume changes. Changes to matrix hydration may therefore alter passive chondrocytes' volume and unless compensated by volume-regulatory pathways, could lead to changes in cell volume, and hence matrix metabolism.
The direct effects of hydrostatic pressure on matrix synthesis in articular cartilage can be studied independently of the other factors that change during loading. We have found that the influence of hydrostatic pressure on incorporation rates of 35SO4 and [3H]proline into adult bovine articular cartilage slices in vitro depends on the pressure level and on the time at pressure. Pressures in the "physiological" range (5-15 MPa) applied for 20 s or for 5 min could stimulate tracer incorporation (30-130%) during the following 2 h, but higher pressures (20-50 MPa) had no effect on incorporation rates. The degree of stimulation in cartilage obtained from different animals was found to vary; in some animals none was seen. Stimulation also varied with position along the joint. Physiological pressures (5-10 MPa) applied continuously for the 2-h incubation period also stimulated incorporation rates, but pressures greater than 20 MPa always produced a decrease that was related to the applied pressure and that was reversible. These results suggests that the hydrostatic pressure that occurs during loading is a signal that can stimulate matrix synthesis rates in articular cartilage.
Articular chondrocytes in vivo are exposed to a changing osmotic environment under both physiological (static load) and pathological (osteoarthritis) conditions. Such changes to matrix hydration could alter cell volume in situ and influence matrix metabolism. However the ability of chondrocytes to regulate their volume in the face of osmotic perturbations have not been studied in detail. We have investigated the regulatory volume decrease (RVD) capacity of bovine articular chondrocytes within, and isolated from the matrix, before and following acute hypotonic challenge. Cell volumes were determined by visualising fluorescently-labelled chondrocytes using confocal laser scanning microscopy (CLSM) at 21 degrees C. Chondrocytes in situ were grouped into superficial (SZ), mid (MZ), and deep zones (DZ). When exposed to 180mOsm or 250mOsm hypotonic challenge, cells in situ swelled rapidly (within approximately 90 sec). Chondrocytes then exhibited rapid RVD (t(1/2) approximately 8 min), with cells from all zones returning to approximately 3% of their initial volume after 20 min. There was no significant difference in the rates of RVD between chondrocytes in the three zones. Similarly, no difference in the rate of RVD was observed for an osmotic shock from 280 to 250 or 180mOsm. Chondrocytes isolated from the matrix into medium of 380mOsm and then exposed to 280mOsm showed an identical RVD response to that of in situ cells. The RVD response of in situ cells was inhibited by REV 5901. The results suggested that the signalling pathways involved in RVD remained intact after chondrocyte isolation from cartilage and thus it was likely that there was no role for cell-matrix interactions in mediating RVD.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.