Extracellular Matrix Disorders: Molecular Mechanisms and Treatment Targets
- Sergey Leikin, PhD, Head, Section on Physical Biochemistry
- Elena N. Makareeva, PhD, Staff Scientist
- Edward L. Mertz, PhD, Staff Scientist
- Shakib Omari, PhD, Postdoctoral Fellow
- Anna Roberts-Pilgrim, PhD, Postdoctoral Fellow
- Laura Gorrell, BS, Predoctoral Fellow
- Katrina Y. Koon, BS, Postbaccalaureate Fellow
The extracellular matrix (ECM) is involved in a wide variety of disorders, ranging from rare genetic abnormalities of skeletal development (skeletal dysplasias) to such common ailments as osteoporosis, fibrosis, and cancer. Our interest in ECM biology began with studies on basic principles relating the helical structure of collagen and DNA to their interactions and biological function. Over the years, the focus of our research shifted to collagens, which are the most abundant ECM molecules, and then to ECM disorders and the development of novel treatments for these disorders. We gradually phased out DNA studies and concentrated on ECM pathology in cancer, fibrosis, osteogenesis imperfecta (OI), Ehlers-Danlos syndrome (EDS), chondrodysplasias, osteoporosis, and other diseases. Together with other NICHD and extramural clinical scientists, we strive to improve our knowledge of the molecular mechanisms underlying those diseases. We hope to use the knowledge gained through our studies for diagnostics, characterization, and treatment, bringing our expertise in physical biochemistry and theory to clinical research and practice.
Procollagen folding and its role in bone disorders
Collagens are triple-helical proteins forming the structural scaffolds of many tissues and organs. Type I collagen produced by osteoblasts is the main structural component of the organic bone matrix. By far the most abundant protein in all vertebrates, type I collagen accounts for up to 30% of all proteins synthesized by osteoblasts. Yet, folding of its procollagen precursor within the endoplasmic reticulum (ER) presents an extraordinary challenge for cells. We discovered that the thermodynamically favorable state of type I procollagen at body temperature is a random coil. The natively folded procollagen conformation is more favorable and therefore stable only below 35°C. To fold procollagen at body temperature, cells use the collagen-specific molecular chaperone HSP47 and possibly other specialized ER chaperones to stabilize the native conformation. Outside the cell, the native conformation is stabilized after procollagen is converted to collagen and incorporated into collagen fibrils. Unincorporated molecules denature within several hours after secretion and become susceptible to rapid proteolytic degradation. Our findings indicate that osteoblast malfunction caused by procollagen misfolding is an important factor in bone pathology (Reference 1).
The most common hereditary cause of procollagen misfolding is a Gly substitution anywhere in the obligatory (Gly-X-Y)n sequence of the collagen triple helix. Such substitutions are responsible for over 80% of severe OI cases. Our studies of OI patients with over 50 different Gly substitutions revealed several structural regions within the triple helix where these mutations might be responsible for distinct OI phenotypes. For example, the first 85–90 amino acids at the N-terminal end of the triple helix form an “N-anchor” domain with higher than average triple helix stability. Gly substitutions within this region disrupt the whole N-anchor, preventing normal cleavage of the adjacent N-propeptide. Incorporation of collagen with uncleaved N-propeptides into fibrils leads to hyperextensibility and joint laxity more characteristic of the Ehlers-Danlos syndrome (EDS). Gly substitutions in alpha1(I) within another region, one that surrounds the collagenase cleavage site, might be lethal because the sequence of this region prevents efficient renucleation of normal C-to-N-terminus helix folding, once the mutation is encountered.
Bone pathology associated with excessive procollagen misfolding of nonhereditary origin is likely to be more prevalent than OI. Indeed, our data suggest that such misfolding should occur upon changes in the osteoblast ER environment associated with aging, environmental factors, inflammation, etc. It is likely to contribute to age-related osteoporosis, bone loss during cancer treatment, and many other common ailments. However, almost nothing is known about this pathophysiology mechanism because procollagen folding and consequences of its misfolding for the cell remain poorly understood.
Cell biology of procollagen misfolding
To better understand the fundamental cell biology of procollagen misfolding, we are using live-cell imaging to investigate synthesis, folding, trafficking, and degradation of fluorescently tagged procollagen in osteoblasts. Our study of transiently transfected chains produced several surprises. In particular, live-cell imaging revealed no HSP47 in vesicles shuttling procollagen from the ER to Golgi or in autophagosomes containing misfolded procollagen, contrary to the existing hypotheses. Given that HSP47 preferentially binds to the natively folded triple helix, bound HSP47 has been presumed to be involved in quality control and export of properly folded procollagen from the ER. If confirmed, our finding that HSP47 is released from procollagen in the ER rather than cis-Golgi/ER-Golgi intermediate compartment (ERGIC) is inconsistent with this hypothesis and raises the question as to how HSP47 release in the ER is regulated and whether this release is involved in the ER export mechanism. Our imaging of folded and misfolded procollagen trafficking from the ER, conducted in collaboration with Jennifer Lippincott-Schwartz, suggested novel, alternative hypotheses for the HSP47 release and quality control of procollagen folding in the ER, which are currently under investigation.
In another approach to understanding the cell biology of procollagen misfolding, we are investigating cell-stress response to procollagen with a Gly610 to Cys substitution in the triple helical region of the alpha2(I) chain in a mouse model of OI. The G610C mouse model mimics the Gly610 to Cys mutation found in a large group of patients from an Old Order Amish community in Pennsylvania. Our study of cultured fibroblasts and osteoblasts as well as tissues in this model revealed misfolding and accumulation of mutant molecules in the ER. Increased phosphorylation of the translation initiation factor EIF2α indicated the presence of cell stress, although we found no evidence of conventional unfolded protein response (UPR) signaling. We found that misfolded procollagen molecules are degraded by lysosomes via autophagy rather than by proteasomes via ER–associated degradation. Osteoblasts adapt to procollagen misfolding by enhancing autophagy and thereby reducing excessive accumulation of misfolded procollagen in the ER. Such an adaptation prevents cell death but is not sufficient to prevent abnormal cell function; e.g., we observed a blunted response to stimulation of collagen production by TGF-β as well as abnormal Wnt signaling. Abnormal function of the latter pathways likely contributes to the abnormal osteoblast differentiation and maturation. The osteoblasts produce less and lower-quality bone matrix. Their abnormal differentiation into osteocytes appears to affect matrix mineralization as well. To compensate for reduced bone synthesis by each cell, G610C mice generate more osteoblasts. However, the combination of the resulting increase in bone formation surfaces with reduced bone formation rate at these surfaces disrupts normal bone modeling, causing, e.g., long-term entrapment of poorly organized woven bone between layers of lamellar bone. The disruption of the cortical bone matrix structure leads to more brittle bones, which have an increased susceptibility to fracture upon high energy impact despite normal cortical thickness and slightly higher cortical bone mineral density. (References 1, 2)
Development of novel OI treatments
Based on these and other findings, we hypothesize that bone pathology associated with procollagen misfolding might be at least partially reversed by targeting the cell stress response to misfolded procollagen accumulation in the ER, thereby improving osteoblast function. However, this would not eliminate potentially detrimental effects of secreted mutant collagen in OI bone. Pharmacological treatment of osteoblast malfunction is a more realistic short-term approach to OI than suppression of dominant negative OI mutations by gene therapy or bone marrow transplantation. Moreover, the same approach is likely to be a better long-term strategy for treatment of osteoblast malfunction caused by procollagen misfolding in cases that do not involve pathogenic mutations.
In pursuing this strategy, we are currently targeting procollagen autophagy. Provided that misfolded procollagen accumulation in the ER is indeed involved in osteoblast malfunction, the simplest way to prevent such accumulation is to enhance the natural ability of the cell to remove and degrade the misfolded molecules via autophagy. Our preliminary study of a low protein diet (LPD) effect on G610C mice provided encouraging evidence of improved osteoblast function as well as bone matrix quality and mineralization. However, in addition to enhancing autophagy, LPD also causes cell stress associated with nutrient deprivation and alters animal growth. The latter and other confounding effects made the LPD study difficult to interpret (Reference 2). We are considering intermittent LPD as a potential component of the eventual treatment strategy, but it might still have a variety of unintended consequences. To unequivocally validate autophagy as a target before embarking on optimizing dietary and pharmacological treatments, we are currently pursuing an approach based on altering expression of Atg5, a key gene involved in regulation of autophagosome formation.
Our preliminary experiments confirmed that reduced autophagy causes increased OI severity. In heterozygous G610C animals, with reduced Atg5 expression in all tissues, we observed close to 50% perinatal lethality compared with wild-type littermates, in contrast to negligible/undetectable perinatal lethality of heterozygous G610C mice with normal Atg5 expression. Conditional Atg5 knockout in mature osteoblasts resulted in dramatically increased bone malformations. We are currently investigating conditional Atg5 knockout in osteoblast precursors, switching from low to normal/high Atg5 expression and conditional targeted Atg5 overexpression.
Translational studies of patients with novel or unusual OI and EDS mutations
Abnormal collagen biosynthesis and malfunction of osteoblasts are also important factors in OI that is caused by other collagen mutations as well as by mutations in other proteins. Over the past several years, we assisted several clinical research groups in characterizing collagen biosynthesis and folding in fibroblasts from patients with newly discovered recessive forms of OI and closely related skeletal dysplasias caused by mutations in cartilage-associated protein (CRTAP), prolyl-3-hydrohylase (P3H1), cyclophilin B (CYPB), the collagen-binding molecular chaperone FKBP65, WNT1, the ER–membrane ion channel TRICB, Golgi-membrane metalloprotease S2P, and the transmembrane anterior posterior transformation protein 1 (TAPT1). In particular, our collaboration with Joan Marini suggested that the CRTAP/P3H1/CYPB complex functions as a procollagen chaperone. A deficiency in any of the three proteins delays procollagen folding, although their exact role in procollagen folding remains unclear. More surprisingly, we found no detectable changes in the procollagen folding rate in cultured fibroblasts from patients with FKBP65 mutations. Our data suggest that FKBP65 may affect post-translational modification of procollagen and deposition of collagen matrix by a different mechanism. It remains unclear why some FKBP65 mutations cause severe OI with joint contractures (Bruck syndrome) while others cause joint contractures without pronounced OI (Kuskokwim syndrome) or OI without pronounced joint contractures. Our study of TRICB–deficient cells revealed abnormal conformation and reduced thermal stability of type I procollagen, suggesting dysregulation of collagen chaperones in the ER or direct involvement of TRICB in procollagen folding (Reference 3). Our experiments indicated that pathogenic effects of mutations in the transmembrane protein TAPT1 and in site-2 metalloprotease (S2P) might not be directly related to disruptions in synthesis, folding, or trafficking of procollagen chains (Reference 4).
More recently, in collaboration with Carsten Bonnemann, we investigated collagen biosynthesis abnormalities caused by mutations in collagen prolyl-4-hydroxylase 1 (P4H1), which result in complex developmental abnormalities involving bones and other connective tissues. As expected, we found that patient skin fibroblasts secreted procollagen with significantly reduced thermal stability. However, we found no abnormalities in the procollagen folding or secretion rates and no evidence of misfolded procollagen accumulation in the cell. The latter findings are extremely surprising given that mutant P4H1 results in significantly reduced proline 4-hydroxylation, which is believed to be important for procollagen triple helix folding. We hypothesize that the folding rate is normalized through some compensatory action of procollagen chaperones. Consistently, our ongoing experiments point to abnormal composition of ER chaperones, but much remains to be done before we understand how patient fibroblasts manage to fold and secrete a normal amount of procollagen despite the P4H1 deficiency and how this deficiency causes connective tissue pathology.
Extracellular matrix pathology in tumors and fibrosis
Another important advance from our work of the past several years was the characterization of a collagenase-resistant, homotrimeric isoform of type I collagen and its potential role in cancer, fibrosis, and other disorders. The normal isoform of type I collagen is a heterotrimer of two alpha1(I) chains and one alpha2(I) chain. Homotrimers of three alpha1(I) chains are produced in some fetal tissues, carcinomas, fibrotic tissues, as well as in rare forms of OI and EDS associated with alpha2(I) chain deficiency. We found the homotrimers to be at least 5–10 times more resistant to cleavage by all mammalian collagenases than the heterotrimers, and we determined the molecular mechanism of this resistance. Our studies suggested that cancer cells might utilize the collagen isoform to build collagenase-resistant tracks, thus supporting invasion through stroma of lower resistance.
We also collaborated with the Stratakis lab to investigate bone tumors caused by defects in protein kinase A (PKA), a key enzyme in the cAMP signaling pathway. Initially, we investigated synthesis of type I collagen homotrimers. However, over the last three years, the focus of the study has shifted to abnormal differentiation of osteoblastic cells and deposition of bone within these tumors. We found that knockouts of various PKA subunits cause not only abnormal organization and mineralization of bone matrix but also novel bone structures that had not been previously reported. For instance, we observed free-standing cylindrical bone spicules with osteon-like organization of lamellae and osteocytes but an inverted mineralization pattern, a highly mineralized central core, and decreasing mineralization away from the central core. Currently, we are assisting the Stratakis lab in characterizing abnormal osteoblast maturation, the role of an abnormal inflammatory response, and effects of anti-inflammatory drug treatments in these animals (Reference 5). Improved understanding of bone tumors caused by PKA deficiencies may not only clarify the role of cAMP signaling but also suggest new approaches to therapeutic manipulation of bone formation in skeletal dysplasias.
Multi-modal micro-spectroscopic imaging and mapping of tissues
Label-free micro-spectroscopic infrared and Raman imaging of tissues and cell cultures provides important information about the chemical composition, organization, and biological reactions inaccessible by traditional histology. However, applications of these techniques were severely restricted by light-path instabilities in thin hydrated specimens under physiological conditions. We resolved the problem by designing specimen chambers with precise thermo-mechanical stabilization for high-definition (HD) infrared imaging and Raman micro-spectroscopy, achieving spectral reproducibility up to two orders of magnitude better than with leading commercial instruments. The HD technology was essential for analysis of abnormal collagen matrix deposition by CRTAP– and FKBP65–deficient cells. It has enabled us to assist NIBIB scientists in characterizing a functionalized carbon-nanotube approach to the delivery of anticancer agents into cells that overexpress hyaluronate receptors and is crucial for our current studies of bone structure and mineralization in the mouse models of OI and PKA deficiencies described above.
The power of the technology is best illustrated by our studies of ECM structure and of composition effects on the function of cartilage in a mouse model of diastrophic dysplasia (DTD), an autosomal recessive dysplasia that affects cartilage and bone development and is caused by mutations in the SLC26A2 sulfate transporter, deficient sulfate uptake by chondrocytes, and resulting under-sulfation of glycosaminoglycans in cartilage matrix. In collaboration with Antonella Forlino and Antonio Rossi, we found that the deficiency results in under-sulfation of chondroitin and disorientation of collagen fibers, disrupting a thin protective layer at the articular surface and causing subsequent cartilage degradation. We investigated the relationship between chondroitin under-sulfation and the rate of its synthesis across the growing epiphyseal cartilage, and we built a mathematical model for the sulfation pathway, predicting treatment targets for sulfation-related chondrodysplasias and genes that might contribute to the juvenile idiopathic arthritis recently associated with single nucleotide polymorphisms in the gene encoding the SLC26A2 transporter.
We are extending the technology by combining imaging of bone and cartilage ECM composition and structure with biomechanical measurements at the same length scales. The mechanical properties of bone and cartilage should depend on the deformation length scale because of the heterogeneous microscopic structure and the presence of different macroscopic regions and zones in these tissues. Nevertheless, biomechanical studies are rarely accompanied by mapping of tissue composition and structure. To address the problem, we are collaborating with Peter Basser and Emilios Dimitriadis on mapping cartilage elasticity by force microscopy at length scales appropriate for examining the material properties of the ECM and on combining it with our multimodal imaging technology.
While the ECM plays a key role in normal development and pathology of all tissues, most studies focus on expression of its components rather than its overall organization. Our multimodal imaging technology is helping to close this gap in in vitro studies of tissue sections and cell cultures. To translate these advances into clinical practice, we established a new collaboration with Basser on using the technology to calibrate and test newer methods for noninvasive in vivo ECM studies by the solid-state magnetic resonance imaging (MRI) that is being developed in his laboratory.
In collaboration with Basser and Roberto Romero, we are adapting HD infrared and Raman technologies for quantitative imaging of the structural organization and composition of ECM in the normal and pathological human placenta. Our initial measurements identified several previously unreported features of placental ECM: (1) highly anisotropic organization of fibrin and collagen, which may depend on and affect the blood flow and determine the tissue strength; (2) deposition of cholesteryl ester aggregates in fibrin fibrinoids from maternal blood; and (3) formation of collagen “fibroids” and high collagen content in matrix fibrinoids. From the perspective of practical clinical implications, one of the most promising applications of these spectroscopic approaches is that, by detecting neutrophil invasion, Raman microscopy can rapidly determine whether there is inflammation/infection in placental membranes after delivery. Given that it is essential to know whether the newborn child should be treated with antibiotics, we are currently evaluating whether the Raman technology would be sufficiently accurate and reliable for such testing.
Publications
- Mirigian LS, Makareeva E, Mertz EL, Omari S, Roberts-Pilgrim AM, Oestreich AK, Phillips CL, Leikin S. Osteoblast malfunction caused by cell stress response to procollagen misfolding in alpha2(I)-G610C mouse model of osteogenesis imperfecta. J Bone Miner Res 2016;31:1608-1616.
- Mertz EL, Makareeva E, Mirigian LS, Koon KY, Perosky JE, Kozloff KM, Leikin S. Makings of a brittle bone: unexpected lessons from a low protein diet study of a mouse OI model. Matrix Biol 2016;52-54:29-42.
- Cabral WA, Ishikawa M, Garten M, Makareeva EN, Sargent BM, Weis M, Barnes AM, Webb EA, Shaw NJ, Ala-Kokko L, Lacbawan FL, Hogler W, Leikin S, Blank PS, Zimmerberg J, Eyre DR, Yamada Y, Marini JC. Absence of the ER cation channel TMEM38B/TRIC-B disrupts intracellular calcium homeostasis and dysregulates collagen synthesis in recessive osteogenesis imperfecta. PLoS Genet 2016;12:e1006156.
- Lindert U, Cabral WA, Ausavarat S, Tongkobpetch S, Ludin K, Barnes AM, Yeetong P, Weis M, Krabichler B, Srichomthong C, Makareeva EN, Janecke AR, Leikin S, Rothlisberger B, Rohrbach M, Kennerknecht I, Eyre DR, Suphapeetiporn K, Giunta C, Marini JC, Shotelersuk V. MBTPS2 mutations cause defective regulated intramembrane proteolysis in X-linked osteogenesis imperfecta. Nat Commun 2016;7:11920.
- Saloustros E, Liu S, Mertz EL, Bhattacharyya N, Starost MF, Salpea P, Nesterova M, Collins M, Leikin S, Stratakis CA. Celecoxib treatment of fibrous dysplasia (FD) in a human FD cell line and FD-like lesions in mice with protein kinase A (PKA) defects. Mol Cell Endocrinol 2017;439:165-174.
Collaborators
- Peter Basser, PhD, Section on Quantitative Imaging and Tissue Sciences, NICHD, Bethesda, MD
- Carsten Bonnemann, MD, Neuromuscular and Neurogenetic Disorders of Childhood Section, NINDS, Bethesda, MD
- Peter H. Byers, MD, University of Washington, Seattle, WA
- Paul J. Coucke, PhD, Universitair Ziekenhuis Gent, Ghent, Belgium
- Sarah Dallas, PhD, University of Missouri, Kansas City, MO
- Emilios K. Dimitriadis, PhD, Biomedical Engineering & Physical Science Shared Resource Program, NIBIB, Bethesda, MD
- Motomi Enomoto-Iwamoto, DDS, PhD, University of Pennsylvania, Philadelphia, PA
- Antonella Forlino, PhD, Università degli Studi di Pavia, Pavia, Italy
- Ken Kozloff, PhD, University of Michigan, Ann Arbor, MI
- Jennifer A. Lippincott-Schwartz, PhD, Section on Organelle Biology, NICHD, Bethesda, MD
- Joan C. Marini, MD, PhD, Bone and Extracellular Matrix Branch, NICHD, Bethesda, MD
- George Patterson, PhD, Section on Biophotonics, NIBIB, Bethesda, MD
- Charlotte L. Phillips, PhD, University of Missouri, Columbia, MO
- Pamela G. Robey, PhD, Craniofacial and Skeletal Diseases Branch, NIDCR, Bethesda, MD
- Roberto Romero, MD, Perinatal Research Branch, NICHD, Detroit, MI
- Antonio Rossi, PhD, Università degli Studi di Pavia, Pavia, Italy
- Dan L. Sackett, PhD, Section on Cell Biophysics, NICHD, Bethesda, MD
- Constantine A. Stratakis, MD, D(med)Sci, Section on Endocrinology and Genetics, NICHD, Bethesda, MD
Contact
For more information, email leikins@mail.nih.gov or visit http://physbiochem.nichd.nih.gov.