HtrA1 Inhibits Mineral Deposition by Osteoblasts

Hadfield, Kristen D.; Rock, Claire Farrington; Inkson, Colette A.; Dallas, Sarah L.; Sudre, L.; Wallis, Gillian A.; Boot-Handford, Raymond P.; Canfield, Ann E.

doi:10.1074/jbc.m709299200

Cited by 72 publications

(36 citation statements)

References 63 publications

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“…This enzyme, high-temperature requirement factor A1 (HtrA1) is a secreted serine protease that degrades several matrix components including decorin, fibronectin, aggrecan, type II collagen 30,31 and impairs elastogenesis by cleaving fibulin 5 30 . Interestingly, while HtrA1 protein levels were increased in smLRP1-/- aortic extracts, mRNA levels for htra1 were not altered in these mice (Fig 4b).…”

Section: Resultsmentioning

confidence: 99%

LRP1 Protects the Vasculature by Regulating Levels of Connective Tissue Growth Factor and HtrA1

Muratoglu

Belgrave

Hampton

et al. 2013

ATVB

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Objective LRP1 is a large endocytic and signaling receptor that is abundant in vascular smooth muscle cells (SMC). Mice in which the lrp1 gene is deleted in SMC (smLRP1-/-) on an LDLr-deficient background display excessive PDGF signaling, SMC proliferation, aneurysm formation, and increased susceptibility to atherosclerosis. The objectives of the current studies were to examine the potential of LRP1 to modulate vascular physiology under non-atherogenic conditions. Approach and Results We found smLRP1-/- mice to have extensive in vivo aortic dilatation accompanied by disorganized and degraded elastic lamina along with medial thickening of the arterial vessels resulting from excess matrix deposition. Surprisingly, this was not due to excessive PDGF signaling. Rather, quantitative differential proteomic analysis revealed that smLRP1-/- vessels contain a 4-fold increase in protein levels of high-temperature requirement factor A1 (HtrA1) which is a secreted serine protease that is known to degrade matrix components and to impair elastogenesis resulting in fragmentation of elastic fibers. Importantly, our studies discovered that HtrA1 is a novel LRP1 ligand. Proteomics analysis also identified excessive accumulation of connective tissue growth factor (CTGF), an LRP1 ligand and a key mediator of fibrosis. Conclusions Our findings suggest a critical role for LRP1 in maintaining the integrity of vessels by regulating protease activity as well as matrix deposition by modulating HtrA1 and CTGF protein levels. These studies highlight two new molecules, CTGF and HtrA1, which contribute to detrimental changes in the vasculature and therefore represent new target molecules for potential therapeutic intervention to maintain vessel wall homeostasis.

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Section: Resultsmentioning

confidence: 99%

LRP1 Protects the Vasculature by Regulating Levels of Connective Tissue Growth Factor and HtrA1

Muratoglu

Belgrave

Hampton

et al. 2013

ATVB

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“…However, it wasn’t until several years later that evidence emerged of a possible functional role for HTRA1 in bone formation. Studies performed using mouse-derived osteoblasts demonstrated that despite its upregulation in response to BMP-2, HTRA1 acted as a negative regulator of bone formation [29, 30]. Moreover, the observation that Htra1 -deficient mice have a moderately improved bone phenotype [31], suggested that HTRA1’s influence on bone may go beyond simply affecting mineral formation in vitro .…”

Section: Discussionmentioning

confidence: 99%

“…In support of this, HTRA1 protein has been detected in developing bones in vivo , as well as in fracture callus [9, 15, 19]. However, in contrast to these findings, several studies now exist in which HTRA1 has been demonstrated to impart a negative influence over osteogenesis [29, 30]. Although the cause of these conflicting results remains unclear, it is important to note that inherent differences exist between the cell culture systems used in each of these studies, and may therefore indicate that cell specific effects of HTRA1 need to be taken into account.…”

Section: Introductionmentioning

confidence: 99%

Role of HTRA1 in bone formation and regeneration: In vitro and in vivo evaluation

et al. 2017

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The role of mammalian high temperature requirement protease A1 (HTRA1) in somatic stem cell differentiation and mineralized matrix formation remains controversial, having been demonstrated to impart either anti- or pro-osteogenic effects, depending on the in vitro cell model used. The aim of this study was therefore to further evaluate the role of HTRA1 in regulating the differentiation potential and lineage commitment of murine mesenchymal stem cells in vitro, and to assess its influence on bone structure and regeneration in vivo. Our results demonstrated that short hairpin RNA-mediated ablation of Htra1 in the murine mesenchymal cell line C3H10T1/2 increased the expression of several osteogenic gene markers, and significantly enhanced matrix mineralization in response to BMP-2 stimulation. These effects were concomitant with decreases in the expression of chondrogenic gene markers, and increases in adipogenic gene expression and lipid accrual. Despite the profound effects of loss-of-function of HTRA1 on this in vitro osteochondral model, these were not reproduced in vivo, where bone microarchitecture and regeneration in 16-week-old Htra1-knockout mice remained unaltered as compared to wild-type controls. By comparison, analysis of femurs from 52-week-old mice revealed that bone structure was better preserved in Htra1-knockout mice than age-matched wild-type controls. These findings therefore provide additional insights into the role played by HTRA1 in regulating mesenchymal stem cell differentiation, and offer opportunities for improving our understanding of how this multifunctional protease may act to influence bone quality.

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“…29 The N- and C-terminal domains of HtrA1 comprise an IGFBP-like/Kazal-like tandem domain motif (termed the N-domain) and a PDZ domain, respectively. Both seem largely dispensable for catalytic function, 30 and whereas the PDZ domain facilitates protein–protein interactions by tethering of the HtrA1 protease to specific sites in the ECM or in the cell, 4,26,31 the role of the N-domain remains enigmatic. The domain contains a total of 16 cysteines, all forming part of an intensive disulfide bond network (Figure 1).…”

mentioning

confidence: 99%

The Autolysis of Human HtrA1 Is Governed by the Redox State of Its N-Terminal Domain

et al. 2014

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Human HtrA1 (high-temperature requirement protein A1) belongs to a conserved family of serine proteases involved in protein quality control and cell fate. The homotrimeric ubiquitously expressed protease has chymotrypsin-like specificity and primarily targets hydrophobic stretches in selected or misfolded substrate proteins. In addition, the enzyme is capable of exerting autolytic activity by removing the N-terminal insulin-like growth factor binding protein (IGFBP)/Kazal-like tandem motif without affecting the protease activity. In this study, we have addressed the mechanism governing the autolytic activity and find that it depends on the integrity of the disulfide bonds in the N-terminal IGFBP/Kazal-like domain. The specificity of the autolytic cleavage reveals a strong preference for cysteine in the P1 position of HtrA1, explaining the lack of autolysis prior to disulfide reduction. Significantly, the disulfides were reduced by thioredoxin, suggesting that autolysis of HtrA1 in vivo is linked to the endogenous redox balance and that the N-terminal domain acts as a redox-sensing switch.

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HtrA1 Inhibits Mineral Deposition by Osteoblasts

Cited by 72 publications

References 63 publications

LRP1 Protects the Vasculature by Regulating Levels of Connective Tissue Growth Factor and HtrA1

LRP1 Protects the Vasculature by Regulating Levels of Connective Tissue Growth Factor and HtrA1

Role of HTRA1 in bone formation and regeneration: In vitro and in vivo evaluation

The Autolysis of Human HtrA1 Is Governed by the Redox State of Its N-Terminal Domain

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