1. Introduction
Systemic lupus erythematosus (SLE) is autoimmune, chronic rheumatic disease characterized by a broad spectrum of clinical manifestations and a wide range of autoantibodies production [
1]. The main contributing factors for tissue damage in SLE are autoantibodies and immune complexes deposition. However, pathogenic mechanisms underlying this disease are still unknown and its course and organ involvements are unpredictable [
2,
3].
In addition to antinuclear antibodies (ANA) positivity in the course of SLE other antibodies are observed such as anti-phospholipid (aPL) and anti-neutrophil cytoplasmic (ANCA). The main targets of aPL are proteins bound to anionic phospholipids located on endothelium and other cellular membranes [
4]. In clinical practice, aPL are measured as anticardiolipin (aCL), anti-beta 2 glycoprotein I (aβ2-GPI) antibodies and lupus anticoagulant (LA) test. Persistent aPL positivity, together with thrombotic vascular events, obstetric complications, or both, are the basis for diagnosing the antiphospholipid syndrome (APS) [
4]. APS is considered the most prevalent acquired thrombophilia and is found in 20–35% of SLE patients. The potential pathogenic and diagnostic role of non-criteria aPL has been the matter of discussion for many years. Early studies performed in 1990s have already paid attention to aPL directed against other than cardiolipin antigens in SLE. They documented significantly increased levels of selected aPL in lupus patients and described a wide profile of potential antigens [
5,
6]. However, the clinical significance of most of them has not been clearly assessed. On the contrary, some reports showed increasing evidence of a relationship between the clinical manifestations of APS and antibodies directed against phosphatidylethanolamine (aPE) [
7] and phosphatidylserine (aPS) [
8] in SLE patients [
9,
10]. Moreover, their relation to cardiovascular disorders such as ischemic stroke [
11,
12,
13] and myocardial infarction [
14] was also proved. The current study presents a novel approach as it was aimed at the complex evaluation of an association between the presence of aPE and aPS and various clinical manifestations in the course of the disease including early atherosclerotic changes and cardiovascular manifestations, microcirculatory abnormalities, thromboembolic complications, vasculitis and renal involvement as well as atherosclerotic risk factors, serological profile and applied treatment in SLE patients.
3. Results
The detailed demographic, clinical, laboratory and therapeutic characteristics of the patient group and the controls are presented in
Table 1.
The analysis of the occurrence of aPE and aPS showed the total presence of these autoantibodies (IgG or IgM isotype) in 18.3% and 12.9% of SLE patients, respectively (
p = 0.044 and
p = 0.038). The specific comparison of the prevalence of these antibodies in SLE patients and in the controls is demonstrated in
Table 2.
aPS of IgG isotype was the sole aPL in one patient but no clinical associations were found (
p > 0.05). On the other hand, aPE IgG were the sole aPL in four patients (4.3%). One patient presented a spectrum of vascular involvement, including high values of carotid intima-media thickness (cIMT), vasculitis, Raynaud’s phenomenon and thromboembolic complications. In one patient, high values of cIMT, and in two renal involvement was confirmed. None of these patients fulfilled the APS criteria (
Table 3).
There was also analyzed the relationship between aPS and aPE and APS as well as other aPL in SLE patients. aPS of both isotypes was significantly associated with APS and all classical aPL including aCL, aβ2-GPI and LA. aPE IgM showed significant correlation with APS, aCL and aβ2-GPI. On the other hand, aPE IgG presented significant association only with aCL IgG (
Table 4).
From the whole spectrum of analyzed organ disorders, only microcirculatory abnormalities were associated with aPS. In SLE patients with aPS (both IgG and IgM isotypes) the risk of Raynaud’s phenomenon development was significantly higher (OR = 4.5; 95%CI: 1.26–16.11, p = 0.021).
Further analysis demonstrated important relationship between aPE and the risk of selected clinical manifestations. The presence of aPE IgG was significantly associated with the risk of kidney involvement (OR = 3.5; 95%CI: 1.01–12.18,
p = 0.049) and the occurrence of selected antibodies including adsDNA (OR = 5.10; 95%CI: 1.28–20.32,
p = 0.021), aNuA (OR = 3.53; 95%CI: 1.02–12.26,
p = 0.047), ANCA (OR = 5.10; 95%CI: 1.28–20.32,
p = 0.021) and anti-elastase (aEla) (OR = 5.32; 95%CI: 1.06–26.74,
p = 0.042) (
Table 5).
On the other hand, in patients with aPE IgM we confirmed notably increased risk of cerebral stroke (OR = 20.4; 95%CI: 1.01–413.06,
p = 0.050) (
Table 5).
Moreover, the presence of aPE of both isotypes (IgG and IgM) was significantly associated with increased risk of thickening of carotid intima-media (OR = 4.2; 95%CI: 1.06–16.26,
p = 0.041) in SLE patients. There was also an important association between aPE IgG and/or IgM and smoking status: the long duration of regular smoking (OR = 4.3; 95%CI: 1.25–14.66,
p = 0.021) and the high number (≥20) of cigarettes/day (OR = 8.8; 95%CI: 1.53–50.80,
p = 0.015) (
Table 5).
Furthermore, the presence of aPS IgM was related to left ventricular posterior wall thickening in echocardiographic examination (OR = 5.28; 95%CI: 0.80–34.67; p = 0.083) and thromboembolic disorders (OR = 4.44; 95%CI: 0.82–24.04; p = 0.084) as well as Raynaud’s phenomenon (OR = 2.87; 95%CI: 0.93–8.78; p = 0.066). However, these findings were only on the border of statistical significance.
We did not find any significant relationship between aPS and aPE and other analyzed clinical manifestations, as well as applied treatment (p > 0.05).
We also compared SLE patients with low activity (≤6) with the patients presenting moderate (7–12) and high (>12) activities of the disease according to the SLEDAI scale. We confirmed in patients with SLEDAI score > 6 significantly more frequent presence of renal involvement, Raynaud’s phenomenon and coexistence of APS as well as occurrence of aPL, adsDNA and aHistone (
Table 6). Moreover, the detailed analysis of patients with the highest SLEDAI score (>12) showed in this patient group importantly higher incidences of relaxation disorders, thromboembolic abnormalities, vasculitis and APS coexistence (myocardial infarction and renal involvement were on the border of statistical significance). They also presented wide spectrum of autoantibodies including aPL, ANA (adsDNA, aHistone, aNucleosome, aSm) and ANCA. Additionally, the assessment of lipid profile showed on the border of statistical significance higher frequency of elevated Castelli index comparing to SLE patients with low and moderate SLEDAI scores (
Table 7).
We took into account the classical atherosclerotic risk factors and found significant associations between cardiovascular involvement in SLE patients and hypertension (OR = 4.28; 95%CI: 1.22–15.03; p = 0.023), overweight and obesity (OR = 3.71; 95%CI: 1.31–10.53; p = 0.014), tabagism (OR = 4.48; 95%CI: 1.44–13.92; p = 0.010), LDL-cholesterol (OR = 5.01; 95%CI: 1.49–16.82; p = 0.009), age ≥ 45 in males and ≥ 55 in females (OR = 5.83; 95%CI: 1.21–28.13; p = 0.028), uric acid (OR = 4.35; 95%CI: 1.25–15.17; p = 0.021), diabetes (OR = 7.08; 95%CI: 1.28–39.19; p = 0.25) and homocysteine (OR = 4.63; 95%CI: 1.43–15.05; p = 0.011).
The complex analysis of lipid profile in lupus patients confirmed significant statistical correlations between Castelli index, Kannel index and TG/HDL-cholesterol ratio and atherosclerotic changes in lower extremities arteries as well as thromboembolic disorders (
Table 8).
4. Discussion
The presence of aPL as well as the coexistence of APS are quite common features in the course of SLE. The clinical significance of different aPL, which are not included in the APS criteria, has been intensively studied for many years. Our earlier reports demonstrated the usefulness of anti-prothrombin antibodies (aPT) in the diagnosis of APS in SLE patients and the highest specificity showed aPT IgG (95.12%). Additionally, aPT IgG were significantly associated with selected central nervous system manifestations, and aPT IgM importantly influenced the risk of development of cardiac complications and mononeuropathy. Interestingly, aPT IgA were significantly related to pleurisy and leucopenia, but they did not associate with the coexistence of APS [
27]. Our study, which focused on atherosclerotic changes development in SLE patients, disclosed a significant relationship between aPT IgA and an increase in cIMT, which was confirmed by multivariate backward stepwise analysis [
28].
These findings provoked further research on the clinical utility of other aPL. The current study was aimed at the evaluation of the association between the presence of aPS and aPE and the risk of selected organ manifestations development including cardiovascular disorders, renal involvement and microcirculation abnormalities in the course of SLE. In addition, we assessed connection of aPS and aPE with APS, selected autoantibodies as well as atherosclerotic risk factors providing the complex analysis of the clinical significance of these autoantibodies in SLE patients.
We found aPS in 12.9% and aPE in 18.3% of lupus patients. In one patient, aPS IgG were the sole aPL but we did not find any clinical association. In contrast, four patients with aPE IgG as the sole aPL showed selected vascular manifestations including thromboembolic disorders, vasculitis, atherosclerotic changes and Raynaud’s phenomenon. Our findings are supported by some clinical studies confirming aPE as the only aPL especially in patients suffering from thrombotic disease [
29,
30]. They were also found the sole antibodies in SLE patients with pulmonary embolism [
31], thrombosis [
32], valvulopathy and livedo reticularis [
9]. Moreover, the report on Sneddon’s syndrome confirmed presence of aPE in 54% of patients and they were considered a major factor of microthrombosis of small arteries in this population [
33].
Sanmarco et al. [
34,
35] stated that aPE might be defined a biological variant of APS in patients with unexplained thrombosis. In current study we demonstrated that there is no correlation between aPE IgG and APS as well as majority of other aPL in SLE patients who presented several vascular manifestations as described above, which may support this theory. It might be also hypothesized that patients with aPE, especially of the IgG isotype, should be considered at general vascular risk and screened, apart from thrombosis, for atherosclerotic disorders, microcirculation abnormalities and vasculitis. However, this issue needs further analysis in prospective studies on larger patient groups to fully explain the potential role of aPE in vascular injury development. The significant association between aPS of both isotypes IgG and IgM and APS in SLE patients documented in our study is also well confirmed by other reports [
9,
10,
36,
37].
In the current study, we found an important correlation between aPE and kidney injury. In accordance, the report by
Fialova et al. [
38] on SLE patients with renal involvement confirmed the high frequency of noncardiolipin antibodies including aPE, aPS and anti-phosphatidylinositol antibodies in those patients and underlined the importance of various aPL in selecting patients with lupus nephritis. In addition, the study performed in pediatric SLE patients with biopsy confirmed lupus nephritis showed that patients with aPL more frequently presented class IV nephritis, microthrombi in small arterioles and intra-glomerular microthrombosis, higher creatinine levels and proteinuria in comparison with aPL negative patients [
39]. Our study also showed significant association between aPE IgG, adsDNA and aNuA. adsDNA are markers of SLE and their role in lupus nephritis development and assessment of activity of the disease have been confirmed by many researchers.
Gamal et al. [
40] showed in Egyptian population the importantly higher frequency of APS in SLE patients positive for adsDNA. However, there was no correlation between adsDNA and particular aPL in the analyzed patient group.
Loizou et al. [
41] found the presence of aCL in conjunction with raised levels of adsDNA and anti-C1q antibodies was highly specific for lupus nephritis. The investigation performed in female SLE patients also revealed that adsDNA were remarkably higher in patients with aPL, but there was no relation between adsDNA and renal injury in the patient group [
42]. In this regard our results together with previous observations on the role of IL-23 in lupus nephritis development [
43] might be helpful in understanding pathomechanisms underlying renal injury development in SLE patients and the potential role of aPL in this process. Additionally, significant relationship between aPE IgG and adsDNA might be helpful in the activity of the disease assessment and prediction of exacerbation. However, it needs to be confirmed in further prospective studies. Furthermore, an interesting finding of a correlation between aPE and ANCA was reported in our study. There are little data available in the literature on the coexistence of aPL and ANCA. A report by
Yoo et al. [
44] showed that persistent aPL at diagnosis did affect thrombotic events during follow-up in ANCA-associated vasculitides (AAV) patients suggesting that there are overlapping pathomechanisms triggered by different types of autoantibodies which may affect the vessel wall. On the one hand, aPL provokes a thrombogenic state via various mechanisms including complement and platelets activation, adhesion molecules expression or tissue factor up-regulation. On the other hand, the severity of AAV is considered to be associated with platelet activation markers and coagulation or fibrinolysis indices. Thus, authors state that all kinds of aPL can increase the risk of thrombotic complication in AAV patients at a high rate and preventive antiaggregating or anticoagulation procedures should be taken into consideration in all patients with the concomitant presence of aPL at diagnosis or during follow-up.
Our study also revealed a significant relationship between aPE and cerebrovascular events in SLE patients and remains in accordance with other data. An investigation performed in 185 patients, including SLE patients, suffering from stroke showed aPE in 35% of patients. Furthermore, the presence of aPE was the most frequent finding in patients who were suspected to have an associated APS [
45]. The next study on young non-SLE patients without obvious causes of arterial thromboembolism who underwent ischemic cerebrovascular incidences also demonstrated the presence of wide profile of non-cardiolipin aPL, including aPE. However, the frequency of aPE was lower: 10.4% [
46]. This difference may suggest that aPE is a better serologic marker of cerebrovascular events in patients suffering from systemic connective tissue diseases than in the general population. An interesting case report illustrated the novel findings of aPE in the cerebral spinal fluid of a 15-year-old patient with a documented ischemic stroke suggesting a possibility of an intrathecal production of aPL in the course of central nervous system disorders [
47]. However, this observation needs to be confirmed by further investigations.
Our research showed a significant association between aPE and early atherosclerotic lesions development presented as the increase in cIMT. These data were confirmed by the analysis of the clinical features of 20 patients with aPE only, among whom 17 had symptoms potentially related to APS. The authors pointed out a relationship between aPE and arteriosclerosis with peripheral arteriopathy [
48]. Furthermore, all findings with a prelation of aPE to cerebrovascular involvement, very often based on atherosclerotic origin, indirectly support these observations. A significant association between cIMT and the risk of ischemic stroke also has been well-documented [
25,
49,
50]. Of note, the latest observations on atherosclerosis in SLE patients with coexisting APS showed that atherosclerotic plaques are infiltrating by T helper (Th) cells secreting IL-17 and interferon (IFN)-γ in response to β2-GPI and suggest that β2-GPI drives a local Th17/Th1 inflammatory response, which can be responsible for plaque instability and rupture, leading to atherothrombosis [
51]. Our previous study also supports these data. We have documented a significant association between IL-23, aPLs including aPE IgG and atherosclerotic plaque development in SLE patients [
43]. As IL-23 plays a central role in inflammation including the induction of Th17 cells [
52,
53] these observations might contribute to better understanding of the pathomechanism of SLE and its complications such as atherosclerosis and cardiovascular disease development. Further studies are necessary to fully elucidate this issue.
Additionally, the analysis of aPE and classical atherosclerotic risk factors showed significant correlation with smoking status in SLE patients. aPE was elevated in patients with long history of regular smoking (current and past) and those who smoked more than 20 cigarettes per day. Tabagism is considered to be an important pathogenic factor of systemic autoimmune rheumatic diseases. The risk of developing SLE is also related to the average number of cigarettes smoked per day, cigarette-years of smoking, fraction smoked per cigarette and degree of smoke inhalation. Moreover, smoking status is associated with selected clinical manifestations such as skin involvement, lupus nephritis and thrombotic events as well as pathogenic antibodies production including adsDNA and aPL [
54]. A prospective cohort study in SLE patients revealed that smoking was associated with aCL, aβ2-GPI and LA. Of note, aPL found in patients who did not smoke regularly was not associated with vascular events. Undoubtedly, the relation between smoking and aPL is important in vascular, including atherothrombotic, lesions development in SLE patients [
55,
56]. The causal relationship between these two factors is still unclear. Some authors suggest the “two-hit hypothesis” to explain why aPL alone does not always initiate clinical manifestations of APS [
57]. Further studies are necessary to elucidate this problem.
We also noted in our study a remarkable association between aPS and Raynaud’s phenomenon. There was also trend towards a higher risk of this complication in patients with the presence of aPE, however, these findings were only on the border of statistical significance. The contrary results were shown in other study focused on identification of rare aPL in SLE patients. Admittedly, their influence on the increased frequency of the clinical symptoms and complications of SLE and APS was confirmed, but a relationship between aPS and Raynaud’s phenomenon was not found [
10]. On the other hand, an impact of aPL on microcirculatory abnormalities in SLE patients was shown in a few earlier studies suggesting a possible link between these antibodies and endothelial damage. Patients with the presence of aCL more often developed Raynaud’s phenomenon and livedo reticularis [
58], as well as changes in nailfold capillaroscopy [
59].
Furthermore, we disclosed the trend towards left ventricular posterior wall thickening in SLE patients with aPS. The association between aPL, including aPS, anti-phosphatidylinositol as well as anti-phosphatidic acid antibodies and cardiac impairment in lupus patients was reported indicating an adjunctive role of aPL in these complications developments [
60].
Finally, the cardiovascular risk in lupus patients is a very complex phenomenon. Classical risk factors as well as factors associated with the disease and immune system dysregulation are involved in vascular impairment development. Our study showed significant impact of classical atherosclerotic risk factors, especially dyslipidemia, and activity of the disease on vascular involvement in SLE patients which was also confirmed by other studies [
24,
25,
26].
To summarize, the limitation of our study is a small number of patients presenting high activity of the disease with multiple organ involvement. Nevertheless, the novel approach based on complex analysis of vascular involvement in the course of SLE enabled us to show a noticeable relationship between analyzed autoantibodies, especially aPE, and the risk of vascular manifestations development both in macro- and micro-circulation. Of note, aPE also might serve as a marker of activity of the disease as well as renal involvement in SLE patients. Significant correlation with smoking and early atherosclerotic changes supports in the identification of patients at risk of cardiovascular complications. Moreover, both aPS and aPE increase the risk of development of clinical manifestations of APS in SLE patients. Especially, aPE might expand the diagnostic potential of serological markers in APS diagnosis as they are associated with the risk of thrombotic complications occurrence in SLE patients negative for the aPL included into APS criteria. Further studies with larger number of patients are needed to fully explain the role of rare aPL in pathogenesis of vascular changes development in SLE patients and to establish their diagnostic capability and managing strategy.