Specific Recognition of the Collagen Triple Helix by Chaperone HSP47

Koide, Takao; Nishikawa, Yohei; Asada, Shinichi; Yamazaki, Chisato M.; Takahara, Yoshifumi; Homma, Daisuke L.; Otaka, Akira; Ohtani, Katsuki; Wakamiya, Nobutaka; Nagata, Kazuhiro; Kitagawa, Kouki

doi:10.1074/jbc.m601369200

Cited by 74 publications

(45 citation statements)

References 34 publications

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“…(2). In our opinion, however, the reported data for HSP47 binding to triple helical peptides [17], [19], [40] and to collagen [15], [35] do not support the cooperative binding model proposed in [15].…”

Section: Methodscontrasting

confidence: 84%

“…Note that this is not inconsistent with the well-documented ability of HSP47 to bind to gelatin [35], [38] since a significant fraction of gelatin chains may be folded into triple helices [39]. Thus, we decided to evaluate the extent of the triple helix stabilization expected for type I procollagen based on the binding constants reported in [40].…”

Section: Discussionmentioning

confidence: 96%

“…(5),(6). After substitution of the dissociation constants reported in [40] and T 0 ≈307 K measured above into Eqs. (5),(6), we calculated T 0 + δT as a function of HSP47 concentration without any adjustable parameters.…”

Section: Discussionmentioning

confidence: 99%

“…(5),(6) based on the HSP47 binding sites and dissociation constants reported in [40], as described in Methods (Theoretical analysis). Two possible values of the dissociation constant K d (OGxRG) = 4.6 µM (solid line) and K d (OGxRG) = 0.94 µM (dashed line) were used to account for the uncertainty in HSP47 binding at OGxRG, where x is a variable amino acid.…”

Section: Discussionmentioning

confidence: 99%

“…(5),(6) based on the HSP47 dissociation constants K i f and K j u for yGxRG sequences reported in [40], where y and x indicate variable residues. Since K j u ≥1 mM [40], we neglected the corresponding terms in Eq. (5).…”

Section: Methodsmentioning

confidence: 99%

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Procollagen Triple Helix Assembly: An Unconventional Chaperone-Assisted Folding Paradigm

Makareeva

Leikin

2007

PLoS ONE

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Fibers composed of type I collagen triple helices form the organic scaffold of bone and many other tissues, yet the energetically preferred conformation of type I collagen at body temperature is a random coil. In fibers, the triple helix is stabilized by neighbors, but how does it fold? The observations reported here reveal surprising features that may represent a new paradigm for folding of marginally stable proteins. We find that human procollagen triple helix spontaneously folds into its native conformation at 30–34°C but not at higher temperatures, even in an environment emulating Endoplasmic Reticulum (ER). ER-like molecular crowding by nonspecific proteins does not affect triple helix folding or aggregation of unfolded chains. Common ER chaperones may prevent aggregation and misfolding of procollagen C-propeptide in their traditional role of binding unfolded polypeptide chains. However, such binding only further destabilizes the triple helix. We argue that folding of the triple helix requires stabilization by preferential binding of chaperones to its folded, native conformation. Based on the triple helix folding temperature measured here and published binding constants, we deduce that HSP47 is likely to do just that. It takes over 20 HSP47 molecules to stabilize a single triple helix at body temperature. The required 50–200 µM concentration of free HSP47 is not unusual for heat-shock chaperones in ER, but it is 100 times higher than used in reported in vitro experiments, which did not reveal such stabilization.

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Section: Methodscontrasting

confidence: 84%

Section: Discussionmentioning

confidence: 96%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Procollagen Triple Helix Assembly: An Unconventional Chaperone-Assisted Folding Paradigm

Makareeva

Leikin

2007

PLoS ONE

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Heat Shock Protein 47 ( HSP47 )

Ibrahim

Latip

Abdul‐Wahab

2018

Encyclopedia of Life Sciences

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Heat shock protein 47 (HSP47), a noninhibitory serine protease inhibitor (SERPIN, clade H1) family member, is a unique collagen‐specific molecular chaperone. The binding of HSP47 to collagen has been the subject of intense investigation, as it binds to and only to collagen. This binding specificity presents a relatively unexplored potential of using HSP47 as a target for treatment of collagen‐related diseases and abnormalities. Homology model studies and structural determination have revealed the important amino acid residues for HSP47‐collagen binding interaction. HSP47‐knockout experiment in mice proved the importance of HSP47 for correct folding of collagen triple helices, thus critical for normal development. Various diagnostic and treatment strategies based on the unique HSP47 functions are now being investigated and proposed. Key Concepts Many heat shock proteins (HSPs) act as molecular chaperones to counter the damaging effects of heat, for example unfolding, aggregation and degradation. HSP47 is a collagen‐specific chaperone, essential for collagen biosynthesis. HSP47 binding and release is pH‐dependent, with the involvement of His residues that governs the release. HSP47 has the potential to be used as diagnostic and therapeutic targets in various diseases and abnormalities. HSP47 modulators and inhibitors are under extensive investigation due to its therapeutic potential in many types of diseases.

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Compound heterozygosity for a frameshift mutation and an upstream deletion that reduces expression of SERPINH1 in siblings with a moderate form of osteogenesis imperfecta

Schwarze

Cundy

Liu

et al. 2019

American J of Med Genetics Pt A

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SERPINH1 encodes the collagen chaperone HSP47 that binds to arginine-rich sequences in the type I procollagen trimers and provides the final steps in the folding and stabilization of the triple helical domain. Loss of both alleles in mice results in very early embryonic lethality. SERPINH1 mutations have been associated with one of the rarest forms of recessively inherited osteogenesis imperfecta (OI) with a moderate to severe phenotype. We identified a family with non-consanguineous unaffected parents who had two children with moderate short stature, low bone density, and fractures. Both children were compound heterozygotes for two mutations: a frameshift in the last exon that deleted the RER retention signal, and a 5,274 bp deletion 2.37 kb upstream from the transcription start site. The maternally-inherited frameshift allele was expressed at normal levels, but the protein was unstable. The mRNA encoded by the second allele represented about 50% of that from the frameshift-containing allele.The upstream deletion was inherited from the father, and the mRNA encoded by that allele in his cultured dermal fibroblasts was also expressed at a low level, which confirmed that this domain had a regulatory function for SERPINH1. Regulatory mutations are uncommon causes of human genetic disorders, and the ability to measure expression levels in appropriate cells is key to their identification. K E Y W O R D Scollagen folding, osteogenesis imperfecta, regulatory mutation, RER retention signal, SERPINH1

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Specific Recognition of the Collagen Triple Helix by Chaperone HSP47

Cited by 74 publications

References 34 publications

Procollagen Triple Helix Assembly: An Unconventional Chaperone-Assisted Folding Paradigm

Procollagen Triple Helix Assembly: An Unconventional Chaperone-Assisted Folding Paradigm

Heat Shock Protein 47 ( HSP47 )

Compound heterozygosity for a frameshift mutation and an upstream deletion that reduces expression of SERPINH1 in siblings with a moderate form of osteogenesis imperfecta

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