Impact of urogenital and enterocolitic infections on the onset and evolution of ankylosing spondylitis and psoriatic arthritis

Chișlari Lia; Liliana Groppa; Alexandru Corlateanu; Eugeniu Russu

doi:10.3897/folmed.67.e165847

Abstract

Introduction: Infections such as Chlamydia trachomatis and Yersinia enterocolitica are recognized triggers of reactive arthritis, but their role in chronic spondyloarthritis (SpA)—including ankylosing spondylitis (AS) and psoriatic arthritis (PsA)—remains incompletely defined.

Aim: To evaluate the potential role of selected urogenital and enterocolitic infections in the onset and clinical evolution of AS and PsA.

Materials and methods: This prospective observational study included 1202 patients (709 PsA, 493 AS) followed between 2019 and 2025. Clinical subtypes, disease activity, and imaging features were assessed alongside multiplex PCR and serological screening for C. trachomatis, Mycoplasma spp., Ureaplasma spp., and Y. enterocolitica. Comparisons were made between infection-triggered and idiopathic cases.

Results: Infection was found in 6.2% of PsA and 8.1% of AS patients, which was slightly higher than the control group. Infection-triggered cases presented more often with acute onset, oligoarthritis, and peripheral joint involvement (notably in AS, p=0.002). Over time, PsA showed a shift from oligoarticular to polyarticular and axial forms; axial PsA increased from 2.1% to 21.1% in 2 years. Radiographic and treatment outcomes were comparable between groups. A minority of infection-triggered cases showed remission following antibiotic therapy.

Conclusions: Urogenital and enterocolitic infections may precipitate SpA in a small subset of genetically susceptible individuals, particularly with HLA-B27. While long-term disease trajectories resemble idiopathic forms, early identification of infectious triggers may aid in personalized management strategies. Further research is needed to clarify their role in chronic disease propagation and treatment responsiveness.

Keywords

ankylosing spondylitis, Chlamydia trachomatis, infection-triggered arthritis, spondyloarthritis, psoriatic arthritis

List of abbreviations

AS: ankylosing spondylitis

ASAS: Assessment of SpondyloArthritis international Society

ASAS20: 20% improvement criteria of the ASAS

BASDAI: Bath Ankylosing Spondylitis Disease Activity Index

BASFI: Bath Ankylosing Spondylitis Functional Index

BASMI: Bath Ankylosing Spondylitis Metrology Index

CG: control group

CRP: C-reactive protein

DIP: distal interphalangeal (joints)

DMARDs: disease-modifying antirheumatic drugs

ELISA: Enzyme-Linked Immunosorbent Assay

ESR: erythrocyte sedimentation rate

GI: gastrointestinal

GU: genitourinary

HLA-B27: human leukocyte antigen B27

IBD: inflammatory bowel disease

IgA/IgG: immunoglobulin A / immunoglobulin G

IL: interleukin

IQR: interquartile range

MASES: Maastricht Ankylosing Spondylitis Enthesitis Score

MASEI: Madrid Sonographic Enthesitis Index

MRI: magnetic resonance imaging

NAAT: nucleic acid amplification test

NSAIDs: nonsteroidal anti-inflammatory drugs

PCR: polymerase chain reaction

PsA: psoriatic arthritis

RA: rheumatoid arthritis

ReA: reactive arthritis

SD: standard deviation

SpA: spondyloarthritis

STI: sexually transmitted infection

TNF: tumor necrosis factor

UTI: urinary tract infection

YOPs: Yersinia Outer-Membrane Proteins

Introduction

Ankylosing spondylitis (AS) and psoriatic arthritis (PsA) are two major forms of seronegative spondyloarthritis (SpA)—a group of chronic inflammatory diseases affecting the joints and entheses. AS primarily involves the axial skeleton (sacroiliac joints and spine), whereas PsA often presents with peripheral arthritis associated with psoriasis, though it can also affect the spine.^[1,2] These conditions impose substantial morbidity; they typically begin in young adulthood and can lead to chronic pain, stiffness, and disability. AS has a prevalence of approximately 0.1%–1.4% in the general population, with males more frequently affected, and more than 80%–90% of AS patients carry the HLA-B27 allele.^[2] PsA develops in an estimated 14%–30% of patients with cutaneous psoriasis and contributes significantly to impaired quality of life in this population. The pathogenesis of SpA is multifactorial, involving a complex interplay of genetic predisposition (HLA-B27 and others), immune dysregulation, and environmental factors.^[1,3]

One hypothesized environmental factor is infection. It has long been observed that reactive arthritis can follow certain gastrointestinal or genitourinary infections, and reactive arthritis is classified within the spondyloarthritis spectrum. Urogenital infections with Chlamydia trachomatis are the classic example: C. trachomatis is the most strongly linked pathogen in sexually acquired reactive arthritis, accounting for the majority of non-venereal ReA cases.^[3–5] In retrospective studies, 30%–50% of patients with Chlamydia-induced reactive arthritis develop a chronic or relapsing course of arthritis, sometimes progressing to a clinical picture indistinguishable from primary AS.^[5,6] Chlamydia pneumoniae has also been implicated, though less frequently.^[6] Among enterocolitic infections, Yersinia enterocolitica and Y. pseudotuberculosis are well-documented triggers in Northern Europe—for example, outbreaks of Yersinia food contamination have led to reactive arthritis in ~22% of exposed adults (especially HLA-B27 carriers).‌^[4,7] Similarly, Salmonella, Shigella, and Campylobacter infections can precipitate reactive arthritis, typically within 1-4 weeks of the inciting gastroenteritis. Mycoplasmas and Ureaplasmas are less common pathogens in this context, but case reports and small series have suggested Mycoplasma genitalium (a cause of non-gonococcal urethritis) can lead to reactive arthritis in HLA-B27-positive individuals.‌^[7–9] Ureaplasma urealyticum has been isolated in some patients with reactive arthritis or undifferentiated arthritis, though establishing causality has been challenging.^[8,10] Overall, these infections are thought to act as triggers that induce an immune response, which, in a genetically susceptible host, results in autoimmune or autoinflammatory arthritis even after the pathogen is cleared from the initial site.

Mechanistic theories to explain the link between infection and spondyloarthritis include molecular mimicry (microbial antigens resembling self-proteins, leading to cross-reactive immune responses) and persistent bacterial antigens or occult infection in joint tissues.^[11,12] Notably, DNA or antigen from Chlamydia has been detected in the synovium of patients with chronic reactive arthritis and even in some patients with undifferentiated or axial SpA.‌^[6] This suggests that Chlamydia can evade complete eradication and reside in an intracellular, metabolically altered state in host tissues, perpetuating inflammation. Yersinia and other enteric bacteria have been shown to alter host immune responses; for instance, Yersinia infection can modify HLA-B27 antigen expression on leukocytes, potentially enhancing inflammatory arthritis in B27-positive hosts.^[7] Furthermore, gut microbiome changes have been linked to AS pathogenesis – subclinical gut inflammation is present in up to 50% of AS patients, hinting that chronic exposure to enteric microbial products might drive axial inflammation.^[13] In PsA, chronic skin inflammation and trauma (Koebner phenomenon) are known triggers, but infection may also play a role in certain cases.^[14,15] Streptococcal infection, for example, is associated with guttate psoriasis flares and has been proposed as a trigger for PsA onset in some patients.^[16,17]

Despite these insights, the frequency and clinical impact of specific infections in AS and PsA remain areas of active investigation. Not all patients with AS or PsA have a history of infection, and in those who do, it is often unclear whether the infection was causal or coincidental. The progression from an acute reactive arthritis to chronic AS is reported only in a subset (an estimated 15%-30% of reactive arthritis cases persist or recur chronically).^[4,12] In PsA, infection triggers are less well documented aside from the noted streptococcal association in psoriasis. There is a need to better delineate which patients with SpA have an infection-associated onset and whether their disease course differs (for example, in terms of joint involvement pattern or disease severity).^[3,6,14] This could inform early therapeutic strategies—for instance, the use of antibiotics or more aggressive immunomodulation in those cases.

Aim

The study’s aim was to determine the potential pathogenic role of specific urogenital and enteric infections in causing or modifying the clinical course of spondyloarthritis. This could enhance the understanding of infection-driven immunopathogenesis and identify patients who may benefit from early targeted interventions.

Materials and methods

Study design and population

This longitudinal observational study was conducted at a tertiary rheumatology center between January 2019 and March 2025. A total of 709 patients with psoriatic arthritis and 493 with ankylosing spondylitis were enrolled. PsA diagnosis was based on CASPAR criteria, and patients were stratified into early (<24 months from onset, n=337) and established disease (≥24 months, n=372). AS was defined by the Modified New York (1984) or ASAS axial SpA criteria (2009) and included both radiographic (n=420) and non-radiographic (n=73) cases.

Patients with reactive arthritis, enteropathic arthritis, undifferentiated peripheral SpA, or rheumatoid arthritis (RA) were excluded from the main analysis. However, a comparator cohort included 100 people—50 with cutaneous psoriasis without arthritis and 100 healthy individuals (control group, CG).

The mean age was 40±12 years for AS and 45±13 years for PsA; males predominated in the AS group (67%) and comprised 52% in PsA. Disease duration at inclusion averaged 8.1±6.5 years (AS) and 5.3±4.8 years (established PsA). In 83.8% of PsA cases, psoriasis preceded arthritis onset by a mean of 7 years. Plaque psoriasis was most common; nail involvement was noted in 48%. HLA-B27 was positive in 92% of AS patients and 11% of PsA patients (notably 25% in axial PsA vs. ~7% in purely peripheral forms). All patients were seronegative for rheumatoid factor and anti-CCP antibodies. Ethical approval and informed consent were obtained for all participants.

Infection screening

All participants underwent standardized evaluation for infections with Chlamydia trachomatis, Mycoplasma hominis, M. genitalium, Ureaplasma urealyticum/parvum, and Yersinia enterocolitica. Clinical history targeted recent (≤3 months) genitourinary or gastrointestinal symptoms. Urogenital samples (first-void urine for men; vaginal swabs or urine for women) were tested using validated multiplex PCR for the above pathogens. ELISA was used to detect anti-Yersinia IgA/IgG antibodies (positive if >1:200), and serology for Chlamydia was also performed. Stool cultures or PCR were conducted only in selected cases with recent GI symptoms. All positive results were confirmed in reference laboratories. Identical testing was applied to control groups for baseline prevalence comparison.

Clinical and imaging assessments

At baseline, PsA patients were classified into five subtypes (Moll & Wright): oligoarthritis, DIP-predominant, polyarthritis, axial, and arthritis mutilans. Predominant patterns were recorded, noting overlaps when present. Enthesitis was evaluated clinically and, when needed, by ultrasound using MASES and Glasgow scoring. Dactylitis (acute or chronic) was documented. In AS, peripheral arthritis and spinal mobility (via the Bath AS Metrology Index) were assessed. All patients underwent pelvic and joint radiographs; MRI of the sacroiliac joints/spine was performed in early or unclear cases. Clinical follow-up occurred every 6–12 months, with radiographic progression evaluated biennially in a subset.

Statistical analysis

Data were analyzed using SPSS v. 26. Categorical variables were compared using chi-square or Fisher’s exact test; continuous variables with t-test or Mann-Whitney. Longitudinal within-group changes were assessed by paired t-test or Wilcoxon signed-rank test. Significance was set at p<0.05. Given the exploratory design, no corrections for multiple testing were applied. Results are reported as mean ± SD or median (IQR), as appropriate.

Results

Patient characteristics and baseline infection status

A total of 1202 patients (709 with PsA, 493 with AS) were evaluated. Key baseline characteristics are summarized in Table 1. The PsA and AS groups were generally similar in age, but with a higher male proportion and higher HLA-B27 positivity in AS, as expected. In the PsA cohort, psoriasis duration prior to arthritis averaged 7.4 years; 84% had skin disease preceding joint symptoms, while 16% experienced simultaneous onset of psoriasis and arthritis. Psoriasis severity ranged from mild to moderate in most; 12% had a history of pustular or erythrodermic psoriasis. Nail lesions (onycholysis, pitting) were present in nearly half of PsA patients, often correlating with DIP joint arthritis.

Table 1.

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Baseline characteristics and infection screening results in patients with psoriatic arthritis (PsA) and ankylosing spondylitis (AS)

Characteristic	PsA (n=709)	AS (n=493)	CG (n=150)
Age, mean ± SD (years)	45.2±13.0	40.1±11.8	44.5±12.5 (psoriasis-only subset)
Male sex, %	52%	67%	50% (psoriasis-only), 52% (healthy)
Disease duration, median (years)	3.0 (1.0-8.0)*	6.0 (2.0–12.0)	-
HLA-B27 positive, %	11.3%	92%	8% (psoriasis-only), 6% (healthy)
Prior psoriasis (PsA group only)	83.8%	-	100% (psoriasis)
Infection trigger history (patient-reported)	6.4% (recent infection before arthritis)	4.1% (GI or GU infection pre-back pain)	-
Laboratory infection evidence
C. trachomatis PCR positive	3.1%	4.7%	2.0% (psoriasis-only), 3.3% (healthy)
Mycoplasma genitalium PCR positive	1.3%	1.6%	0.7% (healthy)
M. hominis PCR positive	2.0%	2.4%	1.3% (healthy)
Ureaplasma urealyticum/parvum PCR positive	2.7%	3.2%	2.0% (healthy)
Any above urogenital organism positive (PCR)	6.2%	8.1%	5.3% (healthy)
Yersinia enterocolitica serology (IgA or IgG ≥1:200)	4.0%	5.5%	3.3% (psoriasis-only), 4.0% (healthy)
Elevated CRP >5 mg/L, %	48%	54%	2% (healthy)
BASDAI (0–10, axial disease only)	4.6±2.1 (in axial PsA)	5.8±2.4	-
Tender joint count, median (IQR)	3 (0-8)	0 (0-2) axial-only; 2 (0-5) if peripheral present	0 (healthy)
Swollen joint count, median (IQR)	1 (0-4)	0 (0-0) axial-only; 1 (0-3) with peripheral	0
Enthesitis present (clinical)	45%	35%	0% (healthy)
Dactylitis present (ever)	38% (at baseline)	2% (incidental in AS)	0%

As shown in Table 1, laboratory evidence of infection was relatively infrequent in both groups. Chlamydia trachomatis DNA was detected in 22 PsA patients (3.1%) and 23 AS patients (4.7%). Most of these were asymptomatic for urogenital infection at the time of testing. In those who tested positive, further evaluation often revealed a past history consistent with chlamydial infection (e.g., young male with prior non-gonococcal urethritis). Mycoplasma genitalium was found in <2% of each group, and M. hominis and Ureaplasma in a small fraction; some patients had co-detection of multiple organisms. Overall, 6.2% of PsA and 8.1% of AS patients had at least one urogenital pathogen identified by PCR. These rates were slightly above the healthy control prevalence, but the difference was not statistically significant (OR 1.2, 95% CI 0.7-2.0 for SpA vs. healthy, p=0.48). Meanwhile, serologic evidence of Yersinia exposure was seen in 4.0% of PsA and 5.5% of AS patients. These titers, when positive, were usually low-positive (just above cutoff), and none of the patients had an active Yersinia infection at the time of arthritis onset. The control population had similar low frequencies of Yersinia seropositivity (~3-4%), suggesting background exposure in the community. Thus, on a group level, there was no significant enrichment of past Yersinia infection in SpA patients compared to controls.

When considering patient-reported triggers, 6.4% of PsA patients attributed their arthritis onset to a recent infection (most often a sore throat or diarrheal illness). Interestingly, none specifically reported a chlamydia infection (likely due to lack of symptoms or awareness), whereas a few women noted recurrent UTIs around onset (though those were culture-positive for E. coli, not the atypical organisms studied). In AS, 4.1% recalled a gastrointestinal infection (often unspecified “food poisoning” or traveler’s diarrhea) within 1–2 months before their back pain began; another 2% had a history of reactive arthritis in youth (typically post-dysentery) that had resolved and later progressed to chronic AS years later. By excluding definite reactive arthritis cases from initial enrollment, we intentionally removed patients whose arthritis had clearly begun as an acute post-infectious syndrome. Therefore, the AS and PsA cohorts here largely represent primary idiopathic disease, with only a minority having subtle evidence of infection involvement.

Clinical presentation at onset: infection-triggered vs. non-triggered

Patients with infection-triggered spondyloarthritis (SpA) showed a distinct initial phenotype. Among those with evidence of recent infection (n=50 PsA; n=40 AS), the PsA cases more frequently had acute onset (72% vs. 41%, p<0.001) and oligoarticular patterns (68% vs. 49%), primarily affecting knees, ankles, and mid-foot. DIP joint and finger tenosynovitis were less common early but emerged later. Enthesitis was more prevalent in infection-triggered PsA (60% vs. 44%, p=0.04); dactylitis rates were similar (42% vs. 37%).^[18]

In AS, all had axial involvement by definition. However, 45% of infection-triggered AS patients had peripheral arthritis at onset (vs. ~15% in idiopathic AS, p=0.002), most commonly in knees and ankles. These cases often mimicked reactive arthritis initially. Overall, 12% of AS patients had a mixed axial-peripheral pattern at onset; all infection-triggered AS fell into this group. Uveitis occurred in 25% of AS patients, with no difference by infection status (Fig. 1).

Turning to psoriatic arthritis subtypes, Table 2 summarizes the distribution of clinical forms in early versus established PsA in our cohort. In early PsA (disease <2 years), the most prevalent subtype was asymmetric oligoarthritis (42% of patients), followed by polyarthritis (28%), DIP-joint predominant form (23%), and an isolated axial form was very uncommon (only 2%). None of the early PsA patients had arthritis mutilans at baseline. In established PsA (>5 years disease duration, a subset of 240 patients in our cohort), the pattern had shifted: polyarticular disease became most common (45%), oligoarthritis decreased (20%), DIP involvement as a distinct subset decreased (12%), and axial disease frequency increased substantially (21% had developed axial spondylitis features, up from ~2% initially). The mutilating form (arthritis mutilans) was observed in 5.4% of those with ≥5 years of PsA (consistent with 5%-14% prevalence in long-term disease reported in literature).

Figure 1.

Clinical pattern of joint involvement in ankylosing spondylitis patients at onset, comparing those with an identified infection trigger (n=40) to idiopathic cases (n=453).

Table 2.

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Clinical subtypes of psoriatic arthritis in early versus established disease

PsA clinical form	Early PsA (<2 yrs) n (%)	Established PsA (≥5 yrs) n (%)	p-value (early vs. established)
Asymmetric oligoarthritis	142 (42.1%)	48 (20.0%)	<0.001 (decrease)
Polyarthritis (RA-like)	95 (28.2%)	108 (45.0%)	<0.001 (increase)
DIP joint predominant arthritis	79 (23.4%)	29 (12.1%)	0.003 (decrease)
Axial arthritis (psoriatic spondylitis)	7 (2.1%)	50 (20.8%)	0.006 (increase)
Arthritis mutilans	0 (0%)	13 (5.4%)	0.002 (increase)
Enthesitis (clinical)	115 (34.1%)	150 (62.5%)	<0.001 (increase)
Dactylitis (≥1 digit)	130 (38.6%)	148 (61.7%)	<0.001 (increase)

Fig. 2 depicts the evolution of PsA subtypes over the first 24 months from onset, demonstrating the inverse relationship (“mirror image”) between DIP arthritis and axial arthritis frequencies. The DIP form, initially accounting for 23.4% of cases at onset, dropped to 12.2% at 2 years (p=0.0034), while the axial form increased from 2.1% to 21.1% (p=0.0059). Oligoarthritis also became less dominant as some patients progressed to polyarticular involvement. Notably, in the first year, any axial symptoms in PsA were almost always accompanied by peripheral arthritis (axial PsA rarely occurred in isolation early on; for instance, within 12 months of onset, we saw axial disease only in combination with oligoarthritis in 3 patients and with polyarthritis in 1 patient).

Figure 2.

Evolution of psoriatic arthritis subtypes over time.

In contrast, after several years, a small subset of PsA patients developed primarily axial disease with minimal peripheral involvement, phenotypically converging with AS except for the presence of psoriasis. These findings demonstrate that PsA can spread from peripheral to axial domains as it evolves, and that initial patterns are not always static.

Table 2 shows statistically significant shifts in disease phenotype with longer disease duration. Enthesitis and dactylitis in particular increased markedly in prevalence from early to established PsA (both roughly doubling, p<0.001), reflecting the cumulative burden of these hallmark SpA features. By the time of the >5-year disease, nearly two-thirds of PsA patients had experienced dactylitis at least once, and a similar proportion had enthesitis at one or more sites, demonstrating that these features frequently accumulate over the course of the disease, even if they were not present at the start.

In ankylosing spondylitis (AS), disease onset was characteristically axial. Among early AS cases (<2 years, n≈180), all had sacroiliitis (17% MRI-only), and 45% presented with lumbar spondylitis. By year 2, spinal involvement increased to ~49% (p=0.03), with a shift from lumbar (57%) to thoracic (43%) and cervical (29%) regions suggesting ascending inflammatory progression. Radiographically, syndesmophytes appeared in 15% by 2 years and 28% by 5 years. Hip arthritis was present in 20% at baseline, often in younger patients with high disease activity; 5% required hip replacement.

Infection-related outcomes and disease course

Over a median follow-up of 3 years (up to 6 years in early PsA), we assessed whether infection history influenced arthritis severity or evolution. At baseline, infection-triggered cases had slightly higher CRP/ESR, but inflammatory markers and clinical outcomes equalized after 1 year of standard treatment. Rates of low disease activity were similar: 30% vs. 34% in PsA (p=0.6), and the ASAS20 response in AS was 55% vs. 58% (p=0.7), suggesting no significant impact of infection on treatment response.

Radiographic progression—new erosions in PsA and syndesmophytes in AS—was comparable across groups, indicating that joint damage in the chronic phase is driven largely by host immunity. However, infection-triggered cases more often maintained peripheral arthritis over time. In AS, these patients continued to require DMARDs for peripheral synovitis, unlike idiopathic cases with predominantly axial disease. In PsA, oligoarticular patterns persisted more often in infection-triggered cases, and five such patients achieved prolonged remission following antibiotic therapy, suggesting potential benefit in select cases.

Extra-articular manifestations showed no major differences, though acute uveitis appeared less frequently in infection-triggered AS (10% vs. 26%, p=0.08). No significant differences were found in psoriasis severity or IBD prevalence. One patient with Yersinia-associated AS developed erythema nodosum, consistent with reactive disease features.

Discussion

In this study, we looked at how specific urogenital and gastrointestinal infections, particularly Chlamydia trachomatis, Mycoplasma spp., Ureaplasma spp., and Yersinia enterocolitica, affected the onset and clinical progression of AS and PsA. While the majority of AS and PsA cases appear to develop in the absence of a recognizable infectious trigger, our findings suggest that in a small but significant subset (approximately 3-5%), infection may serve as a precipitating event. This aligns with previous data indicating that C. trachomatis is the leading identifiable cause of sexually acquired reactive arthritis and may contribute to chronic SpA phenotypes in genetically predisposed individuals, particularly those positive for HLA-B27.^[5,6]

Our detection of C. trachomatis DNA in approximately 4-5% of AS and ~3% of PsA patients—rates modestly above the population baseline—supports the hypothesis that persistent or subclinical chlamydial infection may contribute to disease pathogenesis. These findings are notably lower than those reported by Carter et al.^[5], who identified C. trachomatis in the synovial tissue of 62% of patients with undifferentiated SpA using PCR-based analysis of joint biopsies. The disparity is likely attributable to differences in the sampling method, as our screening utilized non-invasive urogenital swabs or urine samples, which may underestimate localized intra-articular infection. Nevertheless, our results lend support to the “hit-and-run” model of spondyloarthritis pathogenesis, in which an acute or subacute infection initiates a self-perpetuating immune cascade that sustains inflammation even after the pathogen has been cleared.

In the case of Yersinia enterocolitica, our observed seroprevalence (~5% in SpA vs. ~4% in controls) is in line with background rates in non-epidemic settings. However, previous outbreaks in Scandinavia, particularly those documented by Gérard et al.^[6], have established that Yersinia can trigger reactive arthritis in a significant proportion of exposed individuals, especially those carrying HLA-B27. Our cohort included several patients with AS whose disease onset followed an acute gastrointestinal illness attributed to Yersinia or Y. pseudotuberculosis – a scenario echoed in the work of Hannu et al.^[7], who reported that 3.5% of patients with ReA progressed to AS over time. These observations strengthen the notion that a subset of idiopathic AS may, in fact, represent post-infectious spondyloarthritis with chronic evolution. This concept is also supported by experimental data from HLA-B27 transgenic rats, which develop spondylitis-like pathology upon enteric bacterial exposure.^[7]

A key strength of our analysis is the detailed comparison between infection-triggered and idiopathic disease presentations. In PsA, infection-triggered cases typically presented with an abrupt, oligoarticular pattern—clinically mimicking reactive arthritis—and showed a higher frequency of enthesitis and involvement of lower-extremity joints (e.g., knees, ankles, and mid-foot). This presentation contrasts with idiopathic PsA, where the disease more often developed insidiously and was characterized by a broader range of patterns, including DIP-predominant and polyarticular forms. Importantly, these differences suggest that early immune activation by microbial antigens may shape disease phenotype at onset. Similar trends were seen in AS: infection-triggered cases more frequently exhibited a mixed axial-peripheral pattern at onset, with 45% showing swollen peripheral joints compared to ~15% in idiopathic AS (p=0.002). These patients were often initially misdiagnosed with reactive arthritis before developing full-blown axial SpA.

Another significant finding from our cohort is the high frequency and progression of enthesitis and dactylitis, which are hallmarks of PsA but are significantly less common in rheumatoid arthritis patients. Importantly, these features may be potentiated by infection: reactive arthritis is classically associated with heel enthesitis and toe dactylitis, suggesting a role for microbial antigens in targeting enthesis-rich anatomical zones – possibly via molecular mimicry with bacterial heat-shock proteins or other conserved structures.^[9]

From a pathogenic perspective, our data support the model in which an environmental trigger, such as a urogenital or enteric infection, initiates immune activation in a genetically susceptible host. While the trigger may be transient, it can initiate an autoinflammatory loop sustained by persistent T-cell activation, local cytokine production, and possibly dysbiosis of gut or skin microbiota.^[13] In PsA, studies have shown increased abundance of Escherichia coli and other microbial shifts that may modulate mucosal immunity.^[4] These mechanisms likely play a larger role in early disease initiation than in later propagation, where the immune response becomes self-sustaining. The similarity in long-term disease activity between infection-triggered and idiopathic SpA in our cohort supports this transition from exogenous to endogenous pathogenic drivers.^[2]

Clinicians should therefore maintain a high index of suspicion for infection in new-onset SpA, especially in patients with abrupt presentations, HLA-B27 positivity, and recent genitourinary or gastrointestinal symptoms. Screening (e.g., for C. trachomatis, Yersinia, and stool pathogens) and prompt treatment may reduce inflammatory burden or prevent further antigenic stimulation. Beyond acute infections, chronic low-grade sources (e.g., periodontal disease) may also amplify systemic inflammation in PsA and should be managed proactively.^[14,15] While some reports have linked vaccinations (including influenza and COVID-19) to PsA flares, our data did not support this association, and the overall benefit-risk ratio of vaccination remains strongly in favor of immunization.^[7,16]

Interestingly, patients in our cohort more often cited psychological stress (14.6%) and physical trauma (~8%) than infection (6.4%) as putative disease triggers. These findings are consistent with previous research on the Koebner phenomenon and support a multifactor model of PsA initiation.^[14] The convergence of environmental, genetic, and immunologic factors complicates attempts at prevention but highlights the diagnostic importance of recognizing recent triggers – be it stress, trauma, or infection – as part of the clinical history.

In comparison to existing literature, our results reinforce key concepts. First, infection-triggered SpA is real but relatively uncommon in PsA. Second, axial PsA increases with disease duration and is frequently underrecognized in early stages. Third, chronic infection may aggravate entheseal inflammation and perpetuate immune dysregulation. And fourth, once chronic SpA is established, infection appears to play a diminishing role in disease activity.

Limitations of the study

This study has several limitations. First, infection identification was based on patient history and peripheral testing (PCR/serology), which may miss asymptomatic or past infections. Joint fluid or synovial tissue PCR was not performed, potentially underestimating microbial persistence. Second, only selected pathogens (Chlamydia trachomatis, Yersinia enterocolitica, and Mycoplasma, Ureaplasma) were screened; other relevant microbes (e.g. Salmonella and Shigella) were not systematically evaluated. Third, the follow-up period (median 3 years) may be too short to capture long-term outcomes such as axial fusion or arthritis mutilans. Fourth, treatment was not standardized; although care followed clinical guidelines, variability in timing and type of therapy could influence results. Finally, the single-center design and regional epidemiology may limit generalizability. Broader, multicenter studies with immunological profiling are needed to confirm and expand these findings.

Conclusions

Our findings demonstrate that urogenital and enterocolitic infections—particularly Chlamydia trachomatis and Yersinia enterocolitica—can act as triggers in a subset of patients with SpA, initiating an acute, reactive-like disease that may evolve into chronic AS or PsA. These infection-associated forms often begin with prominent peripheral arthritis and enthesitis, but over time, their clinical trajectory and treatment needs converge with idiopathic cases, highlighting the self-sustaining nature of the inflammatory process.

In PsA, we observed a predictable evolution from peripheral oligoarthritis to polyarticular and axial involvement, often accompanied by progressive dactylitis and enthesitis. In AS, while axial involvement predominates from the outset, infection-triggered cases more commonly exhibit a mixed axial-peripheral phenotype. In both conditions, infections appear to act as initiators in genetically susceptible individuals, particularly those carrying HLA-B27.

These findings emphasize the importance of early screening for infections in new-onset SpA. Timely identification and treatment of infectious triggers may alleviate acute symptoms and limit immune activation, though their impact on long-term disease control remains uncertain. Early diagnosis and aggressive management, especially in PsA, are critical to preventing structural damage and functional decline.

Ultimately, recognizing infection-triggered SpA supports a precision medicine approach. Further research should explore microbial biomarkers, the utility of anti-infective therapies in defined subgroups, and the long-term benefits of integrated infection and inflammation control strategies in spondyloarthritis.

Funding

The authors have no funding to report.

Competing interests

The authors have declared that no competing interests exist.

Acknowledgements

The authors have no support to report.

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