Isolation and culture of fibroblasts from endoscopic duodenal biopsies of celiac patients

Celiac disease (CD), the most common chronic enteropathy in Western countries, affects genetically predisposed subjects carrying HLA-DQ2 or DQ8 after the ingestion of prolamins (gliadins) present in wheat, rye and barley; Although the CD pathogenesis is largely unknown, it is considered an autoimmune disease due to the abnormal activation of immune system and the presence of autoantibodies [1, 2]. Different cell types (enterocytes, lymphocytes B and T, macrophages, dendritic and mesenchymal cells) participate in the development of the CD small bowel mucosal damage, characterised by lymphocytic infiltration and villous architectural rearrangement [3, 4], and in particular fibroblasts (FBs) seem to have a central role due to their involvement in inflammatory mechanisms and tissue remodelling. The traditional idea of FBs has been evolved from merely extracellular matrix (ECM) producers to transducers of complex environmental stimuli, supporting their central role in the pathogenesis of different human pathologies such as fibrotic diseases, infections, tumors and autoimmune disorders [5‐7]. The biological functions exerted by FBs are linked to the secretion of enzymes (metalloproteases-MMPs, tissue inhibitor of metalloprotease-TIMP, transglutaminase type 2-TG2) [8‐12], cytokines and chemokines (transforming growth factor β-TGFβ, tumor necrosis factor α-TNFα, interferon γ-IFNγ, interleukins-ILs, monocyte and granulocyte chemotactic proteins, RANTES) [13‐17], prostaglandines [18], proteins of the extracellular matrix (ECM) [19]. Moreover, they take part in the intercellular network through the presence on their cell membrane and in the intracellular space of different types of receptors (receptors for E series of prostaglandins, insulin-like growth factor 1 receptor, 5-HT receptor-associated proteins, nuclear fibroblast growth factor receptor-1 and cytokine receptors) [5, 20‐22]. Researches about the involvement of FBs in CD are actually obstructed by the absence of a specific models; we therefore aimed this study to isolate and culture primary FBs from endoscopic duodenal biopsies of CD and non-CD subjects, to analyze the growth patterns of the cultures and to compare the basic morphometric characteristics of FBs.

Sixty CD and 114 non-CD duodenal bioptic specimens were successfully obtained from EGDSs and from each biopsy a similar amount of tissue weight was processed from CD and non-CD (54.9 mg ± 6.4 vs 56.7 mg ± 4.8; respectively; p = ns). All the CD patients on a gluten containing diet had villous atrophy (type 3 lesion); among the CD patients on GFD, all serologically negative, histology showed type 0, 1, 2 and 3a in 2 cases each and type 3b in 1 case. Non CD patients were all classified as type 0.

After 8–12 days of culture, FB-like cells growing radially from the chopped and enzymatically digested bioptic pieces were observed; their lateral spreading increased dimensionally during the culture and the first passage was performed at day 30 (range 25–35) with confluent cells (Figure 2 upper panels). Next passages were performed monthly (range 25–40 days). Primary cultures survived for at least six passages and usually died after 180 days (range 170–200) of culture. The duplication time was about 8 days both for CD and non-CD cells (Figure 2 lower panels), with no statistical differences.

Out of the 174 duodenal specimens, 135 (78%; 45 CD, 90 non-CD) completed the entire cycle of culture. The major reasons of unsuccessful were bacterial contamination (18%) and insufficient bioptic material (4%), equally distributed between the 2 groups (data not shown). Sex, age, clinical and dietary status in the CD group (patients following a gluten-containing or a gluten-free diet) did not influence the successful rate or growth indexes of cell cultures.

Immunocytochemistry was positive for FSP and negative for cytokeratin 20 in all the cultured and examined cells (Figure 3).

Q-banding analysis of FBs from CD and non-CD subjects demonstrated a normal and stable karyotype (data not shown).

Morphometrical analysis performed on CD and non-CD FBs images obtained at the same day of culture (Figure 4) showed some significant differences; in particular, CD FBs were greater, with a longer diameter and perimeter and the area was wider even if the circularity index was similar; on the other side the complexity index was decreased, suggesting a change in the cellular membrane-cytoplasm ratio (Table 1). In particular dietary status and the Marsh-Oberhuber histological grading of CD patients did not influenced morphometric parameters.

FBs are known to be involved in inflammation and tissue remodelling, and they play a pivotal role in CD [27]. Unfortunately, till now no experiences have been reported on culturing primary cells obtained from endoscopic duodenal biopsies, the most reliable source of primary intestinal cells. In this study, for the first time, we describe a suitable technique to obtain long-standing primary human FB cultures from endoscopic biopsies.

In the absence of standardised systems, we based FBs extraction method on those used for cultures from surgical pieces, muscle and skin tissue samples [28]. Differently from these specimens, intestinal endoscopic biopsies contain a small amount of a soft tissue and have an important bacterial contamination caused by the common intestinal flora, the manual management of the endoscope and endoscopic forceps, and their passage through the endoscopic channel together with the patients' gastric juice and saliva. For these reasons we used a higher dose of antibiotics and the proteolytic cocktail of enzymes liberase, rather than the traditional collagenase cocktails that are known to contain endotoxin and exert cytotoxic effects on primary cultures with an increase of lipidic intracellular droplets [29]. Liberase is a blend of highly purified enzymes used to improve the isolation and cultures derived from small tissutal specimens, not suitable for mechanical isolation [30‐32].

In our study 96% of the endoscopic samples resulted adequate to obtain cells without differences between the specimens obtained from CD patients and those from control subjects. All the cultured cells were FBs with normal karyotype, as demonstrated by the FSP positivity, cytokeratine 20 negativity, and the Q banding analysis.

The successful rate of cell cultures was 78%, higher than those obtained from transbronchial lung endoscopic biopsies (successful rate 54%) [33], the only available to make a comparison, since there are no data on mesenchymal cell extraction from endoscopic duodenal biopsies. This success rate was not affected by other possible covariates such as the clinical and demographic characteristics of patients suggesting that the stabilization of cell culture is almost technique-dependent. We judged our rate of success acceptable, taking into consideration the technical difficulties and the bacterial load, the most important cause of withdrawal (18%).

In CD, FBs are known to take part in the development of the intestinal damage (villous atrophy) regulating the deposition, degradation and remodeling of the ECM through the secretion of collagen, MMPs, TIMPs, and TG2, usually altered in CD intestinal mucosa [34‐37]. Moreover, FBs cooperate in the establishment of the CD immunomediated reaction and enterocyte differentiation through the secretion of TGFβ and as a target of the celiac autoantibodies, which finally influence their cell cycle inducing an S phase shifting and the TGFβ secretion [38, 39]. However, these observations are derived from studies on immortalised cell lines (NIH 3T3 and IMR90 FB), human umbilical chord-derived FBs and cultured duodenal biopsies. Although these techniques provide important high-technology resources, they have some constrains: immortalised cell lines are important to study cytotoxic effects in a simplified protein/xenobiotic-cell microenvironment, but they are not disease-specific [40‐42]; cultured duodenal biopsies are a human and disease-specific technique, but they survive in laboratory setting for a maximum of 72 hours, conditioning the study of chronic long-term mechanisms [43]. Furthermore, there are no suitable animal models for investigating CD: the Irish setter dog gluten-induced enteropathy and the rhesus macaques non-infectious diarrhoea are the most CD-specific, but they are expensive, not accessible to a high number of researchers, non-human and involve ethical aspects [44, 45].

Thus, the cultures of primary CD FBs represent an important research aid, easy to obtain because all CD patients undergo to EGDS.

By using a morphometric approach, based on five parameters, we found significant differences between cultured control and celiac FBs; in particular, celiac FBs were substantially longer and wider, with a preserved circularity but a reduced complexity index (perimeter/area ratio) if compared with control FBs. These characteristics are specific of celiac FBs independently by the dietary status of the patients and the Marsh-Hoberhuber histologic grading, suggesting a "permanent" alteration. Since it is well known that shape and size of cells are the result of the spatial arrangement of the microtubule cytoskeleton and are closely related to cell function, we cannot exclude that these differences reflect, at least in part, a different functional state and/or a phenotype. It is noteworthy that the reduced perimeter/area ratio suggests for cultured celiac FBs a lower shape complexity, a parameter that normally is under tight control to ensure a normal cell architecture and tissue pattern [46]. At this regard it should be noticed that standard in vitro cell culture models do not represent the in vivo structure, nonetheless the differences observed between control and celiac groups were obtained in the same culture conditions.

Primary cell cultures from duodenal endoscopic biopsies provide human disease-specific material and are easily suitable in all patients; in fact previous studies using primary cultures from the GI tract were performed only by sampling surgical pieces, thus excluding non-surgical patients, that are known to represent the majority of affected ones. The method of cell culture here described could help in the establishment of novel experiments to study the role of FBs in the pathogenesis of the mucosal damage and to test new therapies alternative to the gluten-free diet. In this context, endoscopy can revalue its role from a simple diagnostic and therapeutic method to a determinant technique in basic translational research.