Introduction
Systemic lupus erythematosus (SLE) is a multi-system autoimmune disease characterized by immune dysregulation that results in the production of antinuclear and other autoantibodies, as well as immune complex deposition in the kidneys and other organs. The disease course of SLE is heterogeneous and characterized by unpredictable flares and remissions. Thus, there is a pressing need to identify biomarkers that will facilitate better assessment of disease activity and organ involvement, and provide insight into the relationships between pathogenesis and clinical manifestations.
Recently, we and others have used gene expression microarrays to identify a group of type I IFN-inducible genes (IFIGs) that are significantly upregulated in peripheral blood cells from SLE patients
A number of studies have identified increased plasma concentrations of chemokines, including 'regulated upon activation normal T-cell expressed and secreted' (RANTES), monocyte chemotactic protein (MCP)-1, IL-8, IFN-inducible protein 10 (IP-10), and monokine induced by IFN-γ (MIG), in patients with active SLE
Although the contributions made by chemokines in the pathogenesis of SLE have been studied extensively, the mechanisms that give rise to the increased chemokine responses in peripheral blood cells from SLE patients remain unclear. It has been reported that certain chemokine responses are strongly dependent upon IL-2
In the present study we measured the transcription levels of seven IFN-inducible chemokines, as well as those of five classical IFIGs, in peripheral blood cells drawn from 67 patients with SLE, 20 with rheumatoid arthritis (RA), and 23 healthy donors, and calculated a chemokine score and an IFN score for each participant. We found that the transcriptional levels of IFN-inducible chemokines in peripheral blood cells were closely associated with disease activity and organ damage in SLE, and may be useful in disease monitoring and prognostication.
Materials and methods
Patients and control individuals
This study was approved by the Review Board for RenJi Hospital inShanghai, Republic of China. Informed consent was obtained from all study participants. All studies were performed in accordance with the Declaration of Helsinki. Sixty-seven Chinese patients with SLE, 20 with RA, and 23 age-matched and sex-matched healthy donors were enrolled in the study (Table
Demographics of SLE and RA patients and healthy donors
SLE patients (n = 67)
RA patients (n = 20)
Healthy donors (n = 23)
Age (years)
35.43 ± 1.85 (14–60)
37.2 ± 1.68 (17–61)
32.21 ± 2 (16–58)
Sex (%)
Female
89.6
85
83.3
Male
10.4
15
16.7
Disease duration (years)
5.58 ± 0.75 (0.04–24)
5.93 ± 1.3 (1.2–21)
-
ANA (%)
95.5
37.1
-
SLEDAI-2K
8.06 ± 0.68 (0–25)
-
-
SDI
0.82 ± 0.17 (0–6)
-
-
Except where otherwise indicated, values are expressed as mean ± standard error of the mean (range). There were no significant differences between patients with SLE, patients with RA and healthy donors in terms of age and sex. ANA, antinuclear antibody; RA, rheumatoid arthritis; SDI, Systemic Lupus International Collaborating Clinics/American College of Rheumatology Damage Index; SLE, systemic lupus erythematosus; SLEDAI-2K, SLE Disease Activity Index 2000.
The lupus patients were all receiving steroid therapy at the time of the study, with an average prednisone (or equivalent) dosage of 40 mg/day. In addition, 28 patients were taking immunosuppressive therapy and 28 were receiving an antimalarial drug (hydrochloroquine 200 to 400 mg/day). For each patient, disease activity and disease-related damage were assessed at the time of blood donation using the SLE Disease Activity Index 2000 (SLEDAI-2K)
Sample handling and RNA processing
Peripheral blood samples donated by each participant were collected in tubes containing anticoagulant-citrate-dextrose solution A. After plasma was collected, erythrocytes were lysed immediately and total RNA extracted from leucocytes using Trizol Reagent (Invitrogen, Carlsbad, CA, USA). Traces of DNA contamination were routinely removed by On-column DNase treatment using RNeasy Mini Kit (Qiagen, Hamburg, Germany). The integrity of RNA was assessed using capillary gel electrophoresis, and the quality and quantity of RNA were measured using NanoDrop™ 1000 Spectrophotometer (NanoDrop Technologies, Wilmington, DE, USA) with 260 nm/280 nm ratio above 1.8. About 1 μg total RNA was then reverse transcribed into cDNA using SuperScript II Reverse Transcriptase (Invitrogen). All plasma, RNA and cDNA samples were stored at -70°C before use.
Real-time PCR
To quantify the expression of genes encoding IFN-inducible chemokines and IFIGs, the transcriptional levels of a total of seven IFN-inducible chemokine genes (RANTES, MCP-1, MIG, IP-10, C-X-C chemokine ligand [CXCL]11, IL-8, and C-C chemokine ligand [CCL]19) and five IFIGs (IFN-induced protein with tetratricopeptide repeats [IFIT]1, IFIT3, myxovirus resistance 1 [Mx1], oligoadenylate synthetase [OAS]1, and lymphocyte antigen 6 complex, locus E [Ly6e]) were measured by real-time PCR using SYBR Green. All cDNA samples were amplified in duplicate using Premix Ex Taq™ (Takara, Shiga, Japan), with the expression of ribosomal protein L13a used as an internal control for each sample. Details of the method were described previously
Primers used to amplify transcripts of chemokines and IFIGs
Gene
Forward
Reverse
RPL13A
5'-CTGGAGGAGAAGAGGAAAGA-3'
5'-TTGAGGACCTCTGTGTATTTGTCA-3'
Ly6e
5'-CTTACGGTCCAACATCAGAC-3'
5'-GCACACATCCCTACTGACAC-3'
OAS-1
5'-GAAGGCAGCTCACGA AAC-3'
5'-TTCTTAAAGCATGGGTAATTC-3'
Mx1
5'-GGGTAGCCA CTGGACTGA-3'
5'-AGGTGGAGCGATTCTGAG-3'
IFIT1
5'-TCAAAGTCAGCAGCCAGTCTCA-3'
5'-GCCTCCTTGGGTTCGTCTATAA-3'
IFIT3
5'-AACTACGCCTGGGTCTACTATCACTT-3'
5'-GCCCTTTCATTTCTTCCACAC-3'
RANTES
5'-CGCTGTCATCCTCATTGCTAC-3'
5'-GGGTGACAAAGACGACTGCT-3'
MCP-1
5'-CATTGTGGCCAAGGAGATCTG-3'
5'-CTTCGGAGTTTGGGTTTGCTT-3'
MIG
5'-GAGTGCAAGGAACCCCAGTAGT-3'
5'-TTGTAGGTGGATAGTCCCTTGGTT-3'
IP-10
5'-TTCAAGGAGTACCTCTCTCTAG-3'
5'-CTGGATTCAGACATCTCTTCTC-3'
CXCL11
5'-CAAACATGAGTGTGAAGGGC-3'
5'-ATGCAAAGACAGCGTCCTCT-3'
CCL19
5'-CCTGCTGGTTCTCTGGACTT-3'
5'-CTCACGATGTACCCAGGGAT-3'
IL-8
5'-TGCCAAGGAGTGCTAAAG-3'
5'-CTCCACAACCCTCTGCAC-3'
CCL, C-C chemokine ligand; CXCL, C-X-C chemokine ligand; IFIG, IFN-inducible gene; IFIT, interferon-induced protein with tetratricopeptide repeats; IL, interleukin; IP-10, interferon-inducible protein 10; Ly6e, lymphocyte antigen 6 complex, locus E; MCP, monocyte chemotactic protein; MIG, monokine induced by interferon-γ; Mx1, myxovirus resistance 1; OAS, oligoadenylate synthetase; RANTES, regulated upon activation normal T-cell expressed and secreted.
Calculation of chemokine scores and IFN scores
IFN scores were calculated as described in previous studies
Statistical analysis
Data were analyzed using the SPSS software for Windows (Version 11.0; SPSS Inc., Chicago, IL, USA). The continuous variable data were not normally distributed because of the extremely elevated expression of IFIGs and chemokines in particular patients; consequently, all values were expressed as medians with 25th and 75th percentiles and interquartile ranges (IQRs), and comparisons were conducted using the nonparametric Mann-Whitney test. Correlations between groups were evaluated using the Spearman test.
Results
Increased average chemokine score in SLE patients
The expression of seven IFN-inducible chemokine genes (RANTES, MCP-1, MIG, IP-10, CXCL11, IL-8 and CCL19) and five classic IFIGs (IFIT1, IFIT3, Mx1, OAS1 and Ly6e) in peripheral blood cells from 67 SLE patients, 20 RA patients and 23 healthy donors were measured using real-time reverse transcription PCR. SLE patients, RA patients, and healthy donors did not differ significantly with respect to mean age or sex distribution (Table
Comparison of chemokine and IFN scores between SLE and RA patients, and healthy donors
Comparison of chemokine and IFN scores between SLE and RA patients, and healthy donors. The methods employed to calculate the chemokine score and the IFN score are described in Materials and methods. (a) Chemokine scores were significantly elevated in SLE patients versus RA patients and healthy donors. (b) IFN scores were significantly elevated both in SLE and RA patients versus healthy donors. (c) Chemokine scores were positively correlated with IFN scores in SLE patients. Each symbol represents an individual patient; horizontal lines indicate median values. IFN, interferon; RA, rheumatoid arthritis; SLE, systemic lupus erythematosus.
Correlation of chemokine score with disease activity, as assessed using SLEDAI-2K and hypocomplementaemia
To investigate whether the expression of IFN-inducible chemokines might be related to SLE disease activity, we compared chemokine scores in SLE patients with different levels of disease activity, as assessed using SLEDAI-2K and the level of complement C3. SLE patients were divided into those with stable disease (SLEDAI-2K score 0 to 4), those with a mild flare (SLEDAI-2K score 5 to 10) and those with a moderate to severe disease flare (SLEDAI-2K score > 10), in accordance with the SLEDAI-2K flare system. We found that chemokine scores were significantly greater in SLE patients with a moderate to severe flare of disease than in patients without a flare (
Association of chemokine and IFN scores with disease activity in SLE patients
Association of chemokine and IFN scores with disease activity in SLE patients. Each symbol represents an individual patient; horizontal lines indicate median values. (a) SLE patients with a moderate-to-severe flare of disease (SLEDAI-2K score > 10) had significantly higher chemokine scores than did those without a disease flare (SLEDAI-2K score < 4) at the time of blood donation. (b) Chemokine scores were positively correlated with SLEDAI-2K. (c) Chemokine scores were significantly elevated in SLE patients with a reduced level of complement C3 (<80 mg/dl) compared with those with normal levels of C3. (d) A significantly negative correlation was observed between the chemokine score and C3 level. In addition, IFN scores were also correlated (e) positively with SLEDAI-2K and (f) negatively with C3 level. IFN, interferon; RA, rheumatoid arthritis; SLE, systemic lupus erythematosus; SLEDAI-2K, SLE Disease Activity Index 2000.
When other indicators of disease activity were considered, the chemokine and IFN scores were not significantly correlated with ESR or circulating levels of IgG anti-dsDNA antibody (data not shown). There were no differences in the mean value of chemokine scores between SLE patients with or without rash or arthritis (Table
Chemokine scores by presence or absence of SLE clinical features
Clinical features
SLE clinical features present
SLE clinical features absent
n
Median (interquartile range)
n
Median (interquartile range)
Renal
36
8.32 (1.43 to 19.41)
31
3.39 (-1.43 to +12.48)
NS
Neurological
4
1.27 (-0.65 to +4.17)
63
6.23 (-0.42 to +15.60)
NS
Arthritis
12
5.09 (-2.48 to +13.98)
55
5.93 (0.12 to 14.01)
NS
Serositis
13
5.47 (0.67 to 38.08)
54
5.32 (-0.93 to +13.96)
NS
Rash
22
2.37 (-2.27 to +13.96)
45
7.39 (0.89 to 15.634)
NS
Mucosal ulcer
8
4.21 (1.95 to 14.33)
59
5.93 (-4.46 to +14.01)
NS
Haematological
19
7.39 (-2.77 to +13.91)
48
5.09 (0.59 to 14.81)
NS
Proteinuria
26
8.511 (2.01 to 23.25)
41
3.39 (-1.56 to +12.56)
NS
Autoantibodies
Anti-dsDNA
37
5.47 (-0.32 to +14.17)
30
5.72 (-0.44 to +14.81)
NS
Anti-Ro
24
6.05 (1.85 to 13.96)
43
5.47 (-1.76 to +15.69)
NS
Anti-Sm
13
11.56 (3.89 to 23.82)
54
3.56 (-1.72 to +12.66)
0.0211
Anti-RNP
23
10.28 (3.08 to 18.97)
44
2.95 (-1.72 to +12.56)
0.0212
Anti-nucleosome
24
7.50 (1.63 to 15.69)
43
3.73 (-0.46 to +13.91)
NS
Medical therapy
Predisone dose >30 mg/day
38
4.76 (-1.56 to +12.66)
29
7.72 (2.12 to 19.89)
NS
Immunosuppressants
28
9.98 (0.53 to 17.33)
39
3.08 (-1.43 to +12.65)
NS
CQ/HCQ
28
2.15 (-1.72 to +12.11)
39
8.92 (2.34 to 18.97)
0.0481
anti-dsDNA, anti-double-stranded DNA; CQ, chloroquine; HCQ, hydrochloroquine; NS, not significant; SLE, systemic lupus erythematosus.
Elevated chemokine scores in SLE patients with organ damage
Given that chemokines are involved in tissue damage and inflammation, we next explored whether chemokine scores are related to organ damage in SLE patients. Lupus nephritis (LN) is one of the most serious manifestations of SLE. In our cohort, nearly 55% of patients had either previous or current LN. Patients were considered to have active renal disease if proteinuria was above 0.5 mg/day, haematuria was above 5 red blood cells per high-power field, pyuria was above 5 white blood cells/high-power field, or cellular casts were present. Infection, kidney stones, or other causes of these urine findings were excluded. Chemokine scores among SLE patients with active LN exhibited a positive trend toward elevation versus those without LN (
Elevated chemokine scores in SLE patients with organ damage
Elevated chemokine scores in SLE patients with organ damage. Each symbol represents an individual patient; horizontal lines indicate median values. (a) Chemokine scores exhibited a positive trend toward elevation in patients with active lupus nephritis (LN; n = 26) relative to patients with inactive LN (n = 10) and those with no history of LN (n = 31). (b) In the cohort, 30 patients were receiving daily doses of prednisone under 30 mg at the time of blood draw. Among them, eight patients had current LN, seven had inactive LN and 15 had never experienced renal manifestations of SLE. Patients with active renal disease had significantly higher chemokine scores than those with inactive LN or without LN. (c) Chemokine scores were significantly elevated in SLE patients with chronic and irreversible organ damage (SDI score 1 to 2 or more) compared with those with no damage. (d) Among those patients whose daily dosage of prednisone was less than 30 mg, chemokine scores were also significantly higher in those with versus those without chronic organ damage. (e) Chemokine scores were calculated in four active LN patients at the beginning of and after 12 weeks of treatment. In patient (p) 1, p2 and p3 (who achieved significant clinical improvement after treatment) chemokine scores were notably decreased, whereas in p4 (who had rapidly progressed into renal failure) chemokine score was dramatically increased. LN, lupus nephritis; SDI, Systemic Lupus International Collaborating Clinics/American Society of Rheumatology Damage Index; SLE, systemic lupus erythematosus.
Because prednisone may impair the expression of IFIGs by peripheral blood cells
We also investigated the association between chemokine scores and both chronic and irreversible tissue damage in SLE, comparing scores between SLE patients with different levels of chronic damage, as assessed using SDI. Results revealed significantly elevated chemokine scores in SLE patients with SDI scores of 1 to 2 and those with scores above 2 versus those without tissue damage (
In order to investigate whether the chemokine score is responsive to treatment and changes over time in conjunction with disease activity, we selected four SLE patients who had initial onset of biopsy-proved type IV LN and collected peripheral blood samples at the beginning of treatment and after 3 months of treatment. Three of the patients (patient 1, 3 and 4) used high-dose predisone(1 mg/kg per day) plus monthly pulse of cyclophosphamide (0.8 g/month), whereas the other (patient 2) used predisone plus mycophenolate mofetil (1.5 g/day). After 12 weeks of treatment, two patients (patients 1 and 2) achieved clinical renal remission, with the urinary protein level dropping to less than 0.5 g/24 hour and their daily dosage of predisone tapering to 35 mg. Patient 3 also had great improvement in LN, with dramatic decreases in her urinary protein level (from 6.5 g/24 hours to 0.8 g/24 hours). In concordance with the clinical improvement in nephritis, chemokine scores in these three patients also significantly lowered. In contrast, patient 4 did not respond to therapy and progressed rapidly to renal failure despite aggressive treatment, including repeated pulses of glucocorticoid (500 mg intravenous methylprednisolone) and cyclophosphamide therapies. Three months after the first blood draw, the patient was suffering from severe oedema and ascites, as well as aggravated renal and heart failure. In parallel, the chemokine score in her peripheral blood leucocytes was dramatically elevated compared with baseline (Figure
Although chemokine scores and IFN scores appear to be linked, we did not find significant differences in the mean value of IFN scores between patients with various levels of SDI (
Association of chemokine scores with clinical features in SLE
To assess associations between chemokine scores and clinical manifestations, autoantibody profiles and medication use, the chemokine scores were compared between patients with versus those without certain clinical features. We identified no significant differences in chemokine scores between patients with versus those without rash, mucosal ulcer, arthritis, serositis, and either neurological or haematological manifestations of SLE (Table
When medical therapies were considered, chemokine scores were significantly decreased in patients on antimalarial drugs at the time of blood donation (median = 2.15, IQR = -1.72 to +12.11;
Discussion
In the present study, we selected seven IFN-inducible chemokines (RANTES, MCP-1, CCL19, MIG, IP-10, CXCL11 and IL-8), and we investigated the associations between their combined expression level and specific clinical features of SLE. Of these seven chemokines, MCP-1, RANTES and CCL19 are members of the CC family, and preferably recruit monocytes, macrophages, T cells and dendritic cells. In contrast, MIG, IP-10, CXCL11 and IL-8 are from the CXCL family, the first three of which are chemoattractants of activated T cells, whereas IL-8 is chemotactic for neutrophils
Rather than focusing on individual chemokines, as most previous investigators have done, we investigated the expression of multiple chemokines and assessed the impact that overall chemokine expression has on SLE disease features. We measured the transcription levels of these chemokines in peripheral leucocytes and calculated a chemokine score by combining their expression levels. Given that there are various sources of serum chemokines, other than those produced by peripheral blood leucocytes, measurement of the mRNA levels of these chemokines in peripheral blood cells is possibly a direct indicator of the dysregulation of chemokine expression that exists in peripheral immune cells in patients with SLE. Moreover, the method is simple, inexpensive and has high throughput, making it a suitable approach to gaining an overview of the expression of multiple chemokines.
In the SLE patients included in the study, IFN score was significantly correlated with chemokine scores (Figure
One of the potential explanations for the discrepancy between the expression of IFIGs and IFN-inducible chemokines is the highly complicated regulation of chemokine expression that exists in various diseases. Stimuli other than type I IFNs, such as IL-18 or IL-2, as suggested by previous studies
In the present study we found that chemokine scores were associated with disease activity, as assessed using the SLEDAI-2K score and C3 level, and with ongoing or cumulative organ damage, as assessed based on the presence of active LN or SDI score in SLE patients. An elevated chemokine score may thus be helpful to identify SLE patient with active and severe disease. The preliminary longitudinal data also show that these chemokine scores are responsive to treatment and may change in conjunction with disease activity and severity, suggesting that chemokine score might be used to monitor disease progression and guide therapy. One of the weaknesses of the SLEDAI-2K score is its insensitivity in detecting improvement or worsening in a manifestation, because this can only be recorded as absent or present. For example, although patient 3 (see Figure
Our conclusion that increased overall production of IFN-inducible chemokines by peripheral blood cells is important in the pathogenesis of SLE is supported by a number of published papers. Chemokines may contribute to SLE by recruiting immune and inflammatory cells to target tissues and by altering the normal trafficking and localization of certain populations of immune cells in the body; hence, they may impair the normal function of such cells. In cutaneous lupus erythematosus, MIG and IP-10 have been found to be significantly upregulated in inflamed skin and to help in the recruitment of plasmacytoid dendritic cells (pDCs), the major producers of type I IFN, to the skin
In addition, in a small-scale study we also observed that the expression levels of those IFN-inducible chemokines were notably elevated in CD14+ monocytes compared with T and B lymphocytes from SLE patients, indicating that monocytes might be more important contributors to the chemokine score than lymphocytes (data not shown). Therefore, the number as well as the activation state of the circulating monocytes might be a valuable clinical marker in SLE. In accordance with this assumption, it was recently reported
The patients with anti-Sm or anti-RNP autoantibodies had higher chemokine scores than did SLE patients without these two autoantibodies. An association of chemokine score with anti-Sm and anti-RNP antibodies is, to our knowledge, reported here for the first time. The underlying pathophysiological mechanism for this remains unknown. One possible explanation, however, is that the expression of IFN-inducible chemokines is somewhat linked to the IFN signature. The association between the IFN signature and anti-RNP autoantibodies was reported in earlier studies
Conclusion
The present study provides new evidence that IFN-inducible chemokine gene transcript levels in peripheral blood leucocytes may act as a new and reliable marker for disease activity and organ damage in human SLE. The data also suggest that the type I IFN system may contribute to SLE by modulating the expression of chemokines, linking these two networks in the pathogenesis of SLE. Additional studies are required to elucidate the highly complex interactions between IFIGs and chemokines, especially within the context of specific autoimmune diseases. The findings of such studies will shed new light on the dysregulation of the immune system and the involvement of inflammation in the initiation and perpetuation of autoimmunity.
Abbreviations
CCL: C-C chemokine ligand; CXCL: C-X-C chemokine ligand; IFIG: IFN-inducible gene; IFIT: interferon-induced protein with tetratricopeptide repeats; IFN: interferon; IL: interleukin; IP-10: IFN-inducible protein 10; IQR: interquartile range; Ly6e: lymphocyte antigen 6 complex, locus E; MCP: monocyte chemotactic protein; MIG: monokine induced by IFN-γ; Mx1: myxovirus resistance 1; OAS: oligoadenylate synthetase; PCR: polymerase chain reactions; pDC: plasmacytoid dendritic cell; RANTES: regulated upon activation normal T-cell expressed and secreted; SD: standard deviation; SDI: Systemic Lupus International Collaborating Clinics/American College of Rheumatology Damage Index; SLE: systemic lupus erythematosus; SLEDAI-2K: SLE Disease Activity Index 2000.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
QF, NS and CB designed the study. YG and JC collected clinical data and blood samples. HC participated in RNA extraction and cDNA preparation. QF and XC performed real-time PCR and conducted data analysis. QF, NS and XC wrote the manuscript. CB and NS supervised the study. All authors read and approved the final manuscript.