The prevalence of ACPA is lower in rheumatoid arthritis patients with an older age of onset but the composition of the ACPA response appears identical

The association between age at RA onset and prevalence of ACPA and RF was studied in all five RA cohorts (Leiden Early Arthritis Clinic (EAC), BARFOT, ESPOIR, Umeå, Lund) and anti-CarP was studied in two cohorts (Leiden EAC, BARFOT). The association between age at RA onset and ACPA level was also studied in all five cohorts. Other ACPA characteristics were studied in ACPA-positive RA patients from the Leiden EAC. RA was defined as fulfilling the 1987 classification criteria [1]. The 2010 classification criteria were not used because autoantibodies are heavily weighted in these criteria, which may induce circularity between the parameter that was studied and the reference.

Baseline serum samples were tested for ACPA: Leiden EAC, anti-CCP2 Immunoscan RA Mark 2 (Eurodiagnostica, Arnhem), cutoff 25 U/ml, and anti-CCP2 EliA CCP (Phadia, Nieuwegein, the Netherlands), cutoff 7 U/ml, were used to determine the presence of ACPA, ACPA level studied in samples tested with the anti-CCP2-test from Eurodiagnostica; ESPOIR, anti-CCP2 (DiaSorin, France), cutoff 50 U/ml; BARFOT and Umeå, anti-CCP2 (Eurodiagnostica, Malmö, Sweden), cutoff 25 U/ml; and Lund, anti-CCP2 (Anamar Lund, using commercial kits, Inova Diagnostics, San Diego, CA), cutoff 20 U/ml. IgM RF was determined as follows: Leiden EAC, in-house ELISA; BARFOT, Serodia RA agglutination test (Fujirebio Inc., Tokyo, Japan); ESPOIR: Elisa, Menarini, France; Positive >9 UI/ml); Umeå, in-house ELISA; and Lund (ELISA, Anamar Lund, using commercial kits, Inova Diagnostics, San Diego, CA). IgG anti-CarP antibodies against carbamylated fetal calf serum were determined as described previously in the Leiden EAC [33], cutoff for positivity was based on the mean + 2SD from a set of 204 healthy controls; and in BARFOT the cutoff was based on the 82 controls from the source population [34].

Data on ACPA isotypes, ACPA fine specificity and ACPA avidity were determined as described previously [35] in 157 RA patients included in the Leiden EAC. In short, by measuring ACPA isotypes different antibody subclasses can be distinguished which all differ in their ability to mediate effector responses [38]. ACPA IgG1, IgG2, IgG3, IgG4, IgA and IgM were determined using a sandwich ELISA [37]. The total number of ACPA isotypes in each ACPA-positive patient was used in our analysis. ACPA fine specificity was studied to measure an increase or shift in antigen recognition. To determine ACPA fine specificity, antibodies against the citrullinated and the arginine-containing form of two peptides derived from vimentin (Vim1–16; Vim59–74), two peptides derived from fibrinogen (Fibα 27–43; Fibβ 36–52) and one peptide derived from α-enolase (Eno 5–20) and against citrullinated myelin basic protein were determined by in-house ELISA [36]. The sum of citrullinated antigens recognized by ACPA in each patient was used in our analysis. Finally the avidity of ACPA IgG, as a measure of the strength of the ACPA response, was determined with elution ELISAs [35]. Avidity is presented as the relative avidity index, which was defined as the ratio of the amount of residual antibodies bound to the antigen-coated plate after NaSCN (1 M) elution to the amount of bound antibodies in the absence of NaSCN, expressed as a percentage.

To visually inspect the relation between age of onset and presence of autoantibodies, the proportion of autoantibody-positive and autoantibody-negative patients was plotted for different age groups of each 5 years. If <10 patients were present in the older age groups (BARFOT, Lund), age groups were summed. To statistically evaluate associations with age of onset, logistic regression analyses were performed per cohort with ACPA, RF or anti-CarP as the dependent variable and age of onset as the independent variable. Because descriptive results (Fig. 1, Additional file 1: Figure S1 and Additional file 2: Figure S2) showed that the proportion of autoantibody-positive RA patients decreased after ±50 years of age, a two-phase logistic regression analysis with one change point at 50 years was fitted. Odds ratios of the different cohorts (obtained from regression analyses) were entered in an inverse-weighted meta-analysis. This method weights results with a low standard error stronger than results with a higher standard error, thereby preventing over-representation of less precise data. A random effect model was used. The meta-analysis was performed separately for age of onset <50.0 years and >50.0 years and separately in males and females.

The proportion of ACPA-positive and ACPA-negative RA patients within the Leiden EAC was then compared with ACPA probabilities from the general Dutch population [7]. Within different age categories the risk of being ACPA-positive within the Leiden EAC was divided by the risk of being ACPA-positive within the general Dutch source population, revealing a risk ratio. The same was done for the risk of being ACPA-negative. Risk ratios of ACPA-positivity and ACPA-negativity were plotted for different age categories.

Data on ACPA characteristics were depicted visually for different age groups of each 10 years, and evaluated statistically with linear regression analysis (ACPA level, ACPA avidity) and ordinal regression analysis (ACPA isotypes, ACPA fine specificity), using Bonferroni correction for multiple testing.

Within the Leiden EAC, the association between age of onset and smoking, SE alleles and symptom onset was analyzed with logistic regression analysis, and with C-reactive protein (CRP), erythrocyte sedimentation rate (ESR) and swollen joint count (SJC) with Spearman’s correlation coefficient, using Bonferroni correction for multiple testing. Symptom onset was considered sub(acute) when there was prompt onset (e.g., <1 week), and not a gradual or intermittent onset. All regression analyses were adjusted for gender. Analyses were performed using SPSS version 23.0 (IBM).

Baseline characteristics of all included patients are presented in Table 1. The majority of the included patients were female and the mean age of onset in the different cohorts ranged from 48.9 to 56.7 years. Symptom duration ranged from 18.3 to 43.3 weeks with the longest symptom duration observed in Lund. Within Leiden EAC, BARFOT and ESPOIR about 50% of the included patients were ACPA-positive, while in Umeå and Lund the percentage of ACPA-positive patients was 73.9% and 80.3%.

The proportion of ACPA-positive RA was plotted for all age categories in all five cohorts (Fig. 1). This showed that the proportion of ACPA-positive patients seemed to decrease after age of onset of 50 years. Logistic regression analyses with a change point at 50 years of age and with adjustment for gender were performed for each cohort; odds ratios (ORs) were combined in a meta-analysis. There was no association between the age of onset and the presence of ACPA in RA patients with an age of onset < 50 years (OR 1.01, 95% CI 0.99–1.04). However, age of onset > 50 years was associated with a lower frequency of ACPA-positivity (OR 0.96, 95% CI 0.95–0.97; Fig. 2a). An OR of 0.96 indicates that for a 1-year increase in the age of onset, the odds of being ACPA-positive decrease 4%; thus this reflects 18% per 5-year increase in age. Results were similar when studying ACPA in age categories of 5 years instead of continuously (Additional file 1: Figure S1). Similar results were observed for RF and anti-CarP (Additional file 2: Figure S2, Additional file 3: Figure S3, Fig. 2b, c).

Also when analyses were repeated with a change point at 60 years of age, similar results were obtained (meta-analysis: p < 0.001 for an association between ACPA presence and age of onset in patients aged > 60 years; and no significant association in patients aged < 60 years, p = 0.88).

Then we studied the proportion of ACPA-positive and ACPA-negative patients in relation to the ACPA prevalence of the Dutch source population (Fig. 3). This showed that, for example, in the age group 18–29 the risk of being ACPA-positive was 87 times higher for RA patients compared with individuals from the general population. In line with this, the risk of being ACPA-negative was 0.48 times higher (meaning 52% lower) for RA patients compared with individuals from the general population. The risk ratio for ACPA-negativity increased at older age.

After having studied the presence of ACPA-positive RA, several characteristics of the ACPA response were evaluated within ACPA-positive RA patients. First, ACPA level was analyzed in relation to age of onset; no association between ACPA level and age of onset was observed (Leiden EAC p = 0.49, BARFOT p = 0.21, ESPOIR p = 0.91, Umeå p = 0.34, Lund p = 0.08; Fig. 4). Then within the Leiden EAC the number of ACPA isotypes was evaluated because isotype class switching can lead to an increased diversity of the antibody repertoire. The ordinal regression showed p = 0.03, and was not significant after correcting for multiple testing (cutoff Bonferroni correction p = 0.01, Fig. 5a). No association was observed between age at onset and the ACPA fine specificity (which we presented as the number of recognized citrullinated antigens by ACPA, p = 0.96; Fig. 5b) and the ACPA avidity index (which measures the overall binding strength of the ACPA response to CCP-2, p = 0.62; Fig. 5c). These findings together suggest that the analyzed ACPA characteristics were comparable within different age categories.

The decrease in the relative proportion of ACPA-positive RA patients with increasing age of onset was not paralleled by age-related differences in the ACPA response itself, which suggests that an age-dependent effect on the ACPA response was not the most likely explanation. To further substantiate this, the associations of age with smoking and the HLA-SE alleles were determined, because these are the main risk factors for ACPA-positive RA. The presence of SE alleles remained constant over age of onset (p = 0.54), but the proportion of smokers decreased with increasing age (p < 0.001, Additional file 4: Figure S4). Similar to that observed for ACPA, this decrease was most prominent for RA patients with an age of onset > 50 years.

Another explanation for the higher proportion of ACPA-negative RA at older age of onset is that a group of (autoantibody-negative) patients with different etiopathology was preferentially present at older age and classified as RA. Because some previous studies have reported associations between clinical characteristics (male gender, more often acute onset, higher acute phase reactants) and an older age of onset [4‐6], we aimed to substantiate this in the present data. We evaluated whether the association between age and the presence of autoantibodies was similar in males and females, showing that the effect was more pronounced in males (Additional file 5: Figure S5). Furthermore, an older age of onset was associated with higher CRP levels (ρ = 0.26, p < 0.001), higher ESR levels (ρ = 0.32, p < 0.001) and a higher number of swollen joints (ρ = 0.10, p = 0.001) at first presentation. RA patients presenting at older age also more often had (sub)acute onset of symptoms (p = 0.003, Additional file 6: Figure S6). These findings remained significant after Bonferroni correction (cutoff p = 0.008).

Altogether these data suggest that at older age there is a subgroup of patients who fulfill the classification criteria for RA that is more often male, nonsmoking, has higher acute phase reactants, more often has (sub)acute symptom onset and is also more often ACPA-negative.