Cloning differentially regulated genes from chondrocytes using agarose gel differential display

Elevated expression of hypoxia inducible factor-2alpha in terminally differentiating growth plate chondrocytes

Growth plate chondrocytes exist in a hypoxic environment where it is recognized that hypoxia-inducible factor-1alpha (HIF-1alpha) is essential for their survival. Its regulation of chondrocyte viability may be mediated by the increased expression of vascular endothelial growth factor (VEGF) and glycolytic enzymes. However, the full chondrocyte response to hypoxia and the molecular control of VEGF expression in relation to growth plate differentiation and vascularization remains poorly understood. Using Percoll density gradient centrifugation, chick chondrocytes were separated into populations of different maturational phenotype. A differential display analysis of the populations showed highly upregulated expression of HIF-2alpha mRNA during chondrocyte differentiation. HIF-2alpha is a homologue of the HIF-1alpha transcription factor, both of which play a role in the activation of a number of hypoxia responsive genes. HIF-1alpha mRNA was also found to be expressed, although levels of expression were found to be similar in all of the chondrocyte fractions. The elevated expression of HIF-2alpha during chondrocyte differentiation was accompanied by increased VEGF expression. Analysis of the murine chondrocyte cell line, ATDC5, which undergoes ordered maturation indicated that HIF-2alpha, VEGF, placental growth factor, and glucose transporter-1 expression all increased in parallel with chondrocyte differentiation. This observation was supported by immunohistochemistry on sections of mouse bone which showed staining corresponding to the presence of HIF-2alpha in hypertrophic growth plate chondrocytes. The presence of HIF-2alpha was also observed in articular chondrocytes but was restricted to the superficial tangential zone. HIF-2alpha is, therefore, likely to be involved in the initiation of blood vessel formation and a metabolic shift in the growth plate, processes crucial for endochondral ossification.

Annealing control primer system for identification of differentially expressed genes on agarose gels

We developed GeneFishing technology, an improved method for the identification of differentially expressed genes (DEGs) using our novel annealing control primer (ACP) system. Because of high annealing specificity during PCR using the ACP system, the application of the ACP to DEG discovery generates reproducible, authentic, and long (100 bp to 2 kb) PCR products that are detectable on agarose gels. To demonstrate this method for gene expression profiling, Gene-Fishing technology was used to detect genes that are differentially expressed during development using total RNAs isolated from mouse conceptus tissues at 4.5-18.5 days of gestation. Ten DEGs (DEG1-10) were isolated and confirmed by Northern blot hybridization. The sequence analysis of these DEGs showed that DEG6 and DEG10 are unknown genes.

Regulation of chondrocyte terminal differentiation in the postembryonic growth plate: the role of the PTHrP-Indian hedgehog axis

Chondrocyte differentiation during embryonic bone growth is controlled by interactions between PTHrP and Indian hedgehog. We have now determined that the major components of this signaling pathway are present in the postembryonic growth plate. PTHrP was immunolocalized throughout the growth plate, and semiquantitative RT-PCR analysis of maturationally distinct chondrocyte fractions indicated that PTHrP, Indian hedgehog, and the PTH/PTHrP receptor were expressed at similar levels throughout the growth plate. However, patched, the hedgehog receptor, was more highly expressed in proliferating chondrocytes. Although all fractionated cells responded to PTHrP in culture by increasing thymidine incorporation and cAMP production and decreasing alkaline phosphatase activity, the magnitude of response was greatest in the proliferative chondrocytes. Bone morphogenetic proteins are considered likely intermediates in PTHrP signaling. Expression of bone morphogenetic protein-2 and 4--7 was detected within the growth plate, and PTHrP inhibited the expression of bone morphogenetic protein-4 and 6. Although organ culture studies indicated a possible paracrine role for epiphyseal chondrocyte-derived PTHrP in regulating growth plate chondrocyte differentiation, the presence within the postembryonic growth plate of functional components of the PTHrP-Indian hedgehog pathway suggests that local mechanisms intrinsic to the growth plate exist to control the rate of endochondral ossification.

Application of differential display to immunological research

The majority of immunological processes are mediated by cell-to-cell contact or receptor-ligand interactions that transmit intracellular signals and affect the regulation of transcription in the nucleus. As a consequence, precursor cells develop into their respective lineages and cells differentiate further during an immune response. In order to study changes in normal cells or even cells that have been isolated from diseased tissue, a number of approaches have been developed. One such method, differential display (DDRT-PCR), is a versatile technique for the analysis of gene expression that is based on RT-PCR and denaturing polyacrylamide gel electrophoresis. This technique is applicable to multiple samples of clonal or purified cell populations as well as to complex tissues and can be used to provide mRNA fingerprints. However, the main purpose of DDRT-PCR is to isolate differentially regulated genes in biological systems. The method is carried out without prior hypothesis as to which genes should be examined and so increases the possibility of identifying completely novel and unexpected changes in transcription. A major drawback has been the isolation of false positive clones and the need to confirm the results of analysis by another method. This makes DDRT-PCR labour intensive. A number of strategies have been recommended to reduce these problems, including reverse-northern analysis as a confirmatory step for screening putative differentials. In order to reduce the number of gel fingerprints that would be required to cover all the mRNAs in a cell, several focused approaches have been suggested. These include targeted differential display for the isolation of multigene families that have conserved protein domains or gene signatures and subtractive differential display whereby one population is subtracted from the other prior to screening. The purpose of this review is to provide some guidance to the immunologist who might wish to apply DDRT-PCR in their research. A number of examples where DDRT-PCR has been used successfully in immunological research are included.

Chondrocytes and longitudinal bone growth: the development of tibial dyschondroplasia

Growth plate cartilage is central to the process of bone elongation. Chondrocytes originating within the resting zone of the growth plate proceed through a series of intermediate phenotypes: proliferating, prehypertrophic and hypertrophic, before reaching a terminally differentiated state. Disruption of this chondrocyte maturational sequence causes many skeletal abnormalities in poultry such as tibial dyschondroplasia (TD), which is a common cause of deformity and lameness in the broiler chicken. Cell and matrix components of the growth plate have been studied in order to determine the cause(s) of the premature arrest of chondrocyte differentiation and retention of prehypertrophic chondrocytes observed in TD. Chondrocyte proliferation proceeds normally in TD, but markers of the differentiated phenotype, local growth factors, and the vitamin D receptor are abnormally expressed within the prehypertrophic chondrocytes above, and within, the lesion. Tibial dyschondroplasia is also associated with a reduced incidence of apoptosis, suggesting that the lesion contains an accumulation of immature cells that have outlived their normal life span. Immunolocalization studies of matrix components suggest an abnormal distribution within the TD growth plate that is consistent with a failure of the chondrocytes to fully hypertrophy. In addition, the collagen matrix of the TD lesion is highly crosslinked, which may make the formed lesion more impervious to vascular invasion and osteoclastic resorption. Recent studies have applied the techniques of differential display and semiquantitative reverse transcriptase-polymerase chain reaction to RNA obtained from discrete populations of growth plate chondrocytes of different maturational phenotypes. This strategy has allowed us to compare phenotypically identical cell fractions from normal and TD growth plates in an attempt to identify possible candidate genes for TD.

Expression patterns of chondrocyte genes cloned by differential display in tibial dyschondroplasia

Tibial dyschondroplasia (TD) appears to involve a failure of the growth plate chondrocytes within growing long bones to differentiate fully to the hypertrophic stage, resulting in a mass of prehypertrophic chondrocytes which form the avascular TD lesion. Many biochemical and molecular markers of chondrocyte hypertrophy are absent from the lesion, or show reduced expression, but the cause of the disorder remains to be identified. As differentiation to the hypertrophic state is impaired in TD, we hypothesised that chondrocyte genes that are differentially expressed in the growth plate should show altered expression in TD. Using differential display, four genes, B-cadherin, EF2, HT7 and Ex-FABP were cloned from chondrocytes stimulated to differentiate to the hypertrophic stage in vitro, and their differential expression confirmed in vivo. Using semi-quantitative RT-PCR, the expression patterns of these genes were compared in chondrocytes from normal and TD growth plates. Surprisingly, none of these genes showed the pattern of expression that might be expected in TD lesion chondrocytes, and two of them, B-cadherin and Ex-FABP, were upregulated in the lesion. This indicates that the TD phenotype does not merely reflect the absence of hypertrophic marker genes, but may be influenced by more complex developmental mechanisms/defects than previously thought.

Identification of a family of noncanonical ubiquitin-conjugating enzymes structurally related to yeast UBC6

Ubiquitin-conjugating enzymes (UBCs) selectively target proteins for proteasomal degradation by the covalent attachment of ubiquitin moieties. Yeast UBC6 is unusual in having an active site distinct from all other UBCs and in possessing a transmembrane domain that anchors it to the cytoplasmic surface of the endoplasmic reticulum. During a differential display analysis on chick growth plate chondrocytes we isolated a cDNA encoding a noncanonical ubiquitin-conjugating enzyme (NCUBE1) structurally similar to yeast UBC6. Chick NCUBE1 transcripts were detected in all tissues examined and decreased threefold during chondrocyte terminal differentiation. Database searches identified other related proteins; the human and mouse orthologues of NCUBE1, a second human homologue of yeast UBC6 (NCUBE2), and related proteins from S. pombe, C. elegans, and P. mariana. Together with yeast UBC6 these proteins constitute a distinct family of UBCs sharing a conserved noncanonical active site sequence and a C-terminal transmembrane domain. By analogy with yeast UBC6 they are likely to be localised to the endoplasmic reticulum where they may be involved in targeting retrotranslocated, ER-associated proteins for proteasomal degradation.

A novel integral membrane protein is differentially expressed in the chick growth plate and maps to chromosome 1

The growth plate is a specialised region of cartilage located at the growing ends of long bones in higher vertebrates. It is responsible for longitudinal bone growth and is under the control of many local and systemic factors. The growth plate consists of an orderly arrangement of small proliferative and larger mature hypertrophic chondrocytes. This paper describes the isolation by differential display of a 988-bp cDNA fragment derived from a transcript that is more highly expressed in proliferating rather than hypertrophic chondrocytes of the chick growth plate. Using 3' RACE, a further 939 bp of cDNA sequence was obtained. The 1.9 kb sequence contains a 924-bp open reading frame encoding an unknown 308 amino acid protein. This protein has a putative transmembrane domain near its N-terminus and three dileucine motifs at its carboxy tail. This gene was expressed in all other tissues examined. A polymorphism was identified by SSCP analysis and the gene was mapped to the centromeric region of the short arm of chicken chromosome 1, close to the locus for autosomal dwarfism.

Cloning of the cDNA encoding phenylalanyl tRNA synthetase regulatory alpha-subunit-like protein whose expression is down-regulated during differentiation

Hybrid polar compounds (HPCs), such as suberoylanilide hydroxamic acid (SAHA), induce differentiation of transformed cells. Differential display of RNA was used to identify genes whose expression is changed during SAHA-induced differentiation of murine erythroleukemia (MEL) cells. One such cDNA was identified whose mRNA level decreased by 50% after 8h of SAHA treatment as determined by Northern blot analysis. The full-length cDNA (1944bp in length) was cloned by sequencing of an EST clone and rapid amplification of 5' cDNA ends (5'-RACE). The predicted amino acid sequence is 589 amino acids and shares 45% identity with the yeast cytoplasmic phenylalanyl tRNA synthetase (PheRS) regulatory alpha-subunit. Human EST clones which share over 90% identity of predicted amino acid sequence with this cDNA map to chromosome 2 near the paired box homeotic gene 3 (PAX3) locus, a region syngenic to mouse chromosome 1. This is the first report of the cloning of the full-length cDNA for the murine PheRS regulatory alpha-subunit-like protein. The level of PheRS alpha-subunit-like mRNA is regulated during differentiation but not during cell cycle progression.

Identification and cloning of a novel phosphatase expressed at high levels in differentiating growth plate chondrocytes

Growth plate chondrocytes progress through a proliferative phase before acquiring a terminally-differentiated phenotype. In this study we used Percoll density gradients to separate chick growth plate chondrocytes into populations of different maturational phenotype. By applying agarose gel differential display to these populations we cloned a cDNA encoding a novel 268 amino acid protein (3X11A). 3X11A contains two peptide motifs that are conserved in a recently identified superfamily of phosphotransferases. It is likely that 3X11A is a phosphatase, but its substrate specificity remains uncertain. 3X11A expression is upregulated 5-fold during chondrocyte terminal differentiation and its expression is approximately 100-fold higher in hypertrophic chondrocytes than in non-chondrogenic tissues. This suggests that 3X11A participates in a biochemical pathway that is particularly active in differentiating chondrocytes.