The role of H19/miR-675 in chondrocyte function Katarzyna Anna
Author(s)
Dudek, Katarzyna Anna
Type
Thesis or dissertation
Abstract
Human articular cartilage is an avascular and aneural connective tissue covering the bone
ends in the joints of the body. It functions in a hypoxic environment and cartilage cells, the
chondrocytes, have adapted to use hypoxia to drive tissue-specific function. The maintenance of
cartilage matrix homeostasis is an important topic in musculoskeletal research and is a subject of
investigation in my laboratory. Previous work in the group has identified a non-coding RNA transcript
(H19), which was highly expressed in human articular chondrocytes (to the levels of the most
abundant matrix genes COL2A1 and AGC), and showed a pattern of expression strikingly similar to
that of the known differentiated chondrocyte markers. Recently, H19 has been shown to give rise to a
mature microRNA, namely miR-675.
MicroRNAs have emerged as a new class of endogenous modulators of gene expression.
Moreover, it was recently shown that microRNAs are essential for normal cartilage development in
the mouse. Hence, the function of H19/miR-675 was investigated, in particular in terms of its
importance in cartilage matrix gene regulation in normal, non-diseased, human articular chondrocytes.
Overexpression of miR-675 increased type II collagen levels at the mRNA and secreted protein levels,
whereas depletion of primary transcript H19 or inhibition of the mature microRNA (miR-675) caused
a decrease in type II collagen message and protein levels. Finally, overexpression of miR-675 rescued
type II collagen levels in H19-depleted or SOX9-depleted cells.
Initial RNA interference experiments indicated that H19 is strongly regulated by the key
cartilage transcription factor SOX9, as well as by another transcription factor important in
chondrocytes, HIF-2α. These results were subsequently confirmed under endogenous conditions using
chromatin immunoprecipitation assay (ChIP). The binding of these two transcription factors was
found at specific sites downstream (SOX9) and upstream (HIF-2α) of the H19 transcription start site.
Here we present a novel mechanism of COL2A1 regulation via miR-675 in human articular
chondrocytes. We provide evidence that SOX9 directly targets H19, the primary transcript of miR-
675. This microRNA then positively regulates type II collagen in healthy human chondrocytes in an
indirect manner. Additionally, HIF-2α directly binds both SOX9 and H19, thereby increasing levels of
COL2A1 in hypoxia.
ends in the joints of the body. It functions in a hypoxic environment and cartilage cells, the
chondrocytes, have adapted to use hypoxia to drive tissue-specific function. The maintenance of
cartilage matrix homeostasis is an important topic in musculoskeletal research and is a subject of
investigation in my laboratory. Previous work in the group has identified a non-coding RNA transcript
(H19), which was highly expressed in human articular chondrocytes (to the levels of the most
abundant matrix genes COL2A1 and AGC), and showed a pattern of expression strikingly similar to
that of the known differentiated chondrocyte markers. Recently, H19 has been shown to give rise to a
mature microRNA, namely miR-675.
MicroRNAs have emerged as a new class of endogenous modulators of gene expression.
Moreover, it was recently shown that microRNAs are essential for normal cartilage development in
the mouse. Hence, the function of H19/miR-675 was investigated, in particular in terms of its
importance in cartilage matrix gene regulation in normal, non-diseased, human articular chondrocytes.
Overexpression of miR-675 increased type II collagen levels at the mRNA and secreted protein levels,
whereas depletion of primary transcript H19 or inhibition of the mature microRNA (miR-675) caused
a decrease in type II collagen message and protein levels. Finally, overexpression of miR-675 rescued
type II collagen levels in H19-depleted or SOX9-depleted cells.
Initial RNA interference experiments indicated that H19 is strongly regulated by the key
cartilage transcription factor SOX9, as well as by another transcription factor important in
chondrocytes, HIF-2α. These results were subsequently confirmed under endogenous conditions using
chromatin immunoprecipitation assay (ChIP). The binding of these two transcription factors was
found at specific sites downstream (SOX9) and upstream (HIF-2α) of the H19 transcription start site.
Here we present a novel mechanism of COL2A1 regulation via miR-675 in human articular
chondrocytes. We provide evidence that SOX9 directly targets H19, the primary transcript of miR-
675. This microRNA then positively regulates type II collagen in healthy human chondrocytes in an
indirect manner. Additionally, HIF-2α directly binds both SOX9 and H19, thereby increasing levels of
COL2A1 in hypoxia.
Date Issued
2012-02
Date Awarded
2012-08
Advisor
Murphy, Chris
Publisher Department
Medicine: Kennedy Institute of Rheumatology
Publisher Institution
Imperial College London
Qualification Level
Doctoral
Qualification Name
Doctor of Philosophy (PhD)