Project description:Elucidating how cell populations promote onset and progression of intervertebral disc degeneration (IDD) has the potential to enable more precise therapeutic targeting of cells and mechanisms. Single cell RNA-sequencing (scRNA-seq) was performed on surgically separated annulus fibrosus (AF) (19,978; 26,983 cells) and nucleus pulposus (NP) (20,884; 24,489 cells) from healthy and diseased human intervertebral discs (IVD). In both tissue types, we observed depletion of cell subsets involved in maintenance of healthy IVD, specifically the immature cell subsets – fibroblast progenitors and stem cells – indicative of an impairment of normal tissue self-renewal. We also identified tissue-specific changes. In NP, several fibrotic populations were increased in degenerated IVD, indicating tissue-remodeling. In degenerated AF, we identified a novel disease-associated subset, which is a stem cell-derived abnormally differentiated chondrocytic population and expresses disease-promoting genes. It was associated with pathogenic biological processes and the main gene regulatory networks includedthrombospondinsignaling and FOXO1 transcription factor. Our data reveal new insights of both shared and tissue-specific changes in specific cell populations in AF and NP during IVD degeneration. These identified mechanisms and molecules are novel and more precise targets for IDD prevention and treatment.

Project description:The aim of this transcription profiling study was to identify novel genes that could be used to distinguish bovine Nucleus pulposus (NP) cells from articular cartilage (AC) and annulus fibrosus (AF) cells and to further determine their expression in normal and degenerate human intervertebral disc (IVD). This study has identified a number of novel genes that characterise the bovine and human NP and IVD cell phenotypes and allows for discrimination between AC, AF and NP cells.<br><br>

Project description:The intervertebral disc (IVD) is a joint in the spine that facilitates daily movement, comprising of the central nucleus pulposus (NP), surrounded by the annulus fibrosus (AF) and sandwiched between two cartilage endplates that function together as a unit. Changes to the IVD occur with aging, most drastically in the NP where it experiences dehydration and loss of cellularity, directly impacting on the integrity of the biomechanical functions of the IVD. Whilst the static proteome reflects the long-term accumulation of proteins and their turnover over the lifetime of the IVD, this information may not reflect immediate cellular changes that may alter during the course of time. To gain a better understanding of cellular function and protein turnover in disc homeostasis (health) versus aging, we analysed the actively synthesized proteins using the SILAC approach. Clinical specimens from spine surgeries for scoliosis (young samples; NP n=2, AF n=4) or degeneration (aged samples; NP n=1, AF n=1) were used in this study.

Project description:The intervertebral disc (IVD) is a joint in the spine that facilitates daily physical activity, comprising of the central nucleus pulposus (NP), surrounded by the annulus fibrosus (AF) and sandwiched between two cartilage endplates that function together as a unit. Changes to the IVD occur with aging, most drastically in the NP where it experiences dehydration and loss of cellularity, directly impacting on the integrity of the biomechanical functions of the IVD. The proteome reflects the long-term accumulation of proteins and their turnover with time, which cannot be faithfully determined by the transcriptome that reflects only immediate cellular changes. The proteome of the disc, which is predominantly extracellular matrix, may therefore more accurately reflect disc function, and could provide important information about the niche in which disc cells are embedded in and can also impact on cellular function. Unfortunately, the acquisition of young healthy IVD tissues from surgeries are scarce, and it is exceedingly rare to obtain healthy samples with spatial information. Here, we examined three young healthy cadaveric lumbar discs, corresponding to three neighboring levels (L3/4, L4/5 and L5/S1), from one individual (16M); and analysed the proteome profiles of the NP, inner AF (IAF) and outer AF (OAF), in a direction-specific (both lateral and anteroposterior) manner, to gain a reference proteome of healthy discs. We identified that the central-most regions of the disc (including NP and IAF) are similar to each other and there is expression of well characterized NP markers (including KRT8/19, CD109), as well as upregulation of cartilage and cytoskeletal-related proteins (including CHRD, CHRDL2, FRZB). Furthermore, in the PCA plot, there is clear demarcation of inner and outer AF, which was found to express small proteoglycans (BGN, DCN, FMOD, OGN, PRELP) and a unique group of the collagens (COL12A1, COL14A1, COL1A1, COL6A1/2/3) and glycoproteins including CILP, CILP2, COMP, FBN1and THBS1. We also showed that in young disc, the upper levels are more similar to each other than the lower disc levels, and that directional factors (whether the tissue was from an anteroposterior or lateral direction) play minimal roles, although we also identified four modules showing strong directional trends. Using the young proteome as a baseline reference, we then examined three aged cadaveric lumbar discs (with same disc levels as the young) from another older individual (59M) to gain further understanding of age-related changes in the disc. Employing ANOVA, PCA and DEG analyses, the aged inner disc regions (including NP and IAF) were found to have similar profiles, express fewer classical NP markers, and have reduced numbers of differentially expressed proteins (DEPs) in comparison to young disc. Overall, both inner compartments and OAF of the aged disc showed an enrichment of proteins associated with inflammation and degradation. Remarkably, we discovered that in aged disc, the IAF and OAF distinction remains strong, and that the upper lumbar disc was deviated more away from their young counterparts than the lower two levels, with minimal influence by directional differences. Importantly, we further identified an abundance of blood proteins that were highly expressed in inner disc of aged discs, which suggested that age-related changes may have originated from the central NP regions of the disc. We carried out additional validation studies by examining the transcriptome of 2 independent young and aged samples, respectively, and were able to correlate transcriptome to young and aged proteome. Unique and novel to this study, we also correlated MRI imaging of the 3 aged lumbar discs and showed that there is correlation of particular types of proteins with MRI image intensity. In all, this data shed lights on the proteomic changes underlying the ageing IVDs in a region-specific manner.

Project description:To fully apprehend the complex mechanisms responsible for intervertebral disc (IVD) degeneration, one needs to gain a deeper understanding of what characterizes a healthy disc. Using a quantitative proteomic approach, we analyzed methodically the differences existing between IVD genders, levels and components. A total of 2776 proteins were identified and we showed that cross regional but not gender variation existed along the mouse spine. Components comparison established CD109, CD81 and Col12a1 as novel NP and AF markers. NP cell clustering involved Cdh2 and tight junctions whereas early phase of adaptation to hypertonicity, the regulation of cell volume, was ensured by Slc12a2 and Wnk1. AF cells were protected from oxidative stress by expressing Atox1 and Sod3. Finally notochordal-like cells vacuoles were not acidic nor lipid droplets. Altogether, our study provides a first comprehensive landscape of the biology of a healthy murine IVD and identifies mechanisms involved in homeostasis and structure maintenance.

Project description:The intervertebral disc (IVD) is a joint in the spine that facilitates daily physical activity, comprising of the central nucleus pulposus (NP), surrounded by the annulus fibrosus (AF) and sandwiched between two cartilage endplates that function together as a unit. Changes to the IVD occur with aging, most drastically in the NP where it experiences dehydration and loss of cellularity, directly impacting on the integrity of the biomechanical functions of the IVD. We were interested in examining the types of degraded proteins in young and aged disc samples to further understand the protein turnover in aging and homeostasis. We analysed the degradome for degraded proteins using terminal amine isotopic labeling of substrates (TAILS) Clinical specimens from spine surgeries for scoliosis (young samples, n=3) or degeneration (aged samples, n=3) were used in this study.

Project description:Intervertebral disc (IVD) degeneration is often the cause of low back pain. Degeneration occurs with age and is accompanied by extracellular matrix (ECM) depletion, culminating in nucleus pulpous (NP) extrusion and IVD destruction. The changes that occur in the disc with age have been under investigation. However, a thorough study of ECM remodelling is needed, to better understand IVD development and age-associated degeneration. As so, iTRAQ LC-MS/MS analysis of foetus, young and old bovine NPs, was used to define the NP matrisome. The enrichment of Collagen XII and XIV in foetus, Fibronectin and Prolargin in elder samples and Collagen XI in young ones was independently validated. This study provides the first matrisome database of healthy discs during development and ageing, which is key to determine the pathways and processes that maintain disc homeostasis. The factors identified may help to explain age-associated IVD degeneration or constitute putative effectors for disc regeneration.

Project description:Description: The intervertebral disc (IVD) is a joint in the spine that is comprised of three major structures, the nucleus pulposus (NP), annulus fibrosus (AF) and cartilaginous endplate (EP). The NP is a proteoglycan-rich structure which contains a heterogenous population including the presence of progenitors such as the notochordal-like cells (NLCs) and NP cells, which are responsible for the synthesis and turnover of extracellular matrix in the NP. During aging and degeneration, there is a loss of cells, hydration, and changes in the ECM, that leads to the alterations in the biomechanical function of the IVD. The replenishment of cells, in particular, the progenitors are a potential therapy for IVD degeneration. However, a major challenge lies in obtaining sufficient numbers of healthy cells for treatment. This study used a 3 part protocol to differentiate pluripotent stem cells into NLCs in vitro.

Project description:Intervertebral disc (IVD) is often the cause of low back pain. Degeneration occurs with age and is accompanied by extracellular matrix (ECM) depletion, culminating in nucleus pulpous (NP) extrusion and IVD destruction. Although the changes that occur with ageing in the IVD have been under study, not much attention has been given to ECM remodelling during normal development. Therefore, a thorough study of ECM composition and a comprehensive view on how this microenvironment is affected in normal ageing conditions is needed, to better understand the processes involved in IVD development and in age-associated degeneration. We have compared the NP matrisome of bovine IVDs from foetus, young and old animals by quantitative iTRAQ LC-MS/MS. Protein expression levels of the most interesting candidates were validated by Western Blot analysis. In total, 161 bovine proteins were identified. Of these, 77 molecules were common to the three different age groups, of which 36 defined the NP matrisome. Differential expression levels obtained for Collagen Type XI, XII, XIV, Fibronectin and Prolargin were independently confirmed. Herein, we demonstrate a shift in NP matrisome signatures that occurs in healthy bovine IVDs with development and ageing. Thus, this study provides insight into factors that may explain age-associated IVD degeneration, and which are putative targets for therapy. It also highlights key molecules, characteristic of early developmental stages, which constitute potential effectors in IVD regeneration.

Project description:During embryonic development, the notochord is the precursor to the nucleus pulposus (NP) in the intervertebral disc (IVD), where the notochord cells differentiate to become notochordal-like cells in the NP, and are considered as potential progenitor cells to support the function of the NP. With aging and degeneration, there is a loss of these cells from the NP which ultimately affects IVD function. The characterisation of the molecular signature of the 8 week-old (gestational age) human embryonic notochord is a valuable resource to better understand the development from the notochord to the NP progenitors and as a benchmark for comparison to other datasets.