Expression of the TP in human control and PAH lung tissue
While signalling through the thromboxane receptor (TP) is implicated in the pathogenesis and progression of PAH, few studies have examined the expression of the TP in human PAH lung tissue. Herein, the expression of the TPα and TPβ isoforms of the TP was examined in lung tissue from control individuals and PAH patients (Figure 1). As a control, expression of the prostacyclin receptor (IP), a related existing PAH drug target, was also investigated.
Positive TPα & TPβ expression was observed in numerous cell types in both control and PAH lung tissue (Figure 1A & B). Specifically, within the pulmonary arteries, TPα & TPβ were strongly expressed within the vascular endothelium, in both control tissue (Figure 1A(ii), 1A(iii) & 1A(v), indicated by arrowheads) and PAH tissue (Figure 1B(ii), 1B(iii) & 1B(v)). Expression of both TPα & TPβ was also observed within the smooth muscle of pulmonary arteries, in both control tissue (Figure 1A(ii), 1A(iii) & 1A(v)) and PAH tissue (Figure 1B(ii), 1B(iii) & 1B(v)). Abundant expression of TPα & TPβ was also noted within plexiform lesions, the characteristic morphological hallmark of advanced PAH (Figure 1B(iv)). These complex and disorganised networks of vascular channels result primarily from endothelial hyperproliferation, combined with increased muscularisation, inflammation and fibrosis.(22) Within these structures, TPα & TPβ were expressed in the endothelial core and the surrounding SM (Figure 1B(v)), and also in inflammatory infiltrates within and adjoining the plexiform lesion (Figure 1B(vi)). Furthermore, within immune cells of inflammatory infiltrates in both control and PAH lungs, while predominantly negative for expression of TPα, these infiltrates showed abundant expression of TPβ (Figure 1A(vi) & 1B(vi), indicated by arrowheads). Additionally, strong expression of both TPα and TPβ was noted in alveolar macrophages (Figure 1A(vi) & 1B(vi)). Positive expression of the IP was primarily restricted to the vascular endothelium, being virtually absent from the vascular SM, with staining also evident in alveolar macrophages (Figure 1A(ii), 1A(iii) & Figure 1A(vi) , indicated by arrowheads).
Hence, these investigations demonstrate abundant expression of both TPα and TPβ isoforms of the TP in the human lung, both in normal control and PAH disease tissues. Bearing in mind this widespread expression of the TP within multiple cell and tissue types within the lung, these findings lend support the investigation of TP antagonism as an approach in the treatment of PAH.
Effect of NTP42 on pulmonary and cardiac haemodynamics in the MCT-PAH rat model
A gold-standard preclinical disease model for studying the effects of new drugs on the development of PAH is the monocrotaline (MCT)-induced PAH model, typically carried out in rodents. This study aimed to investigate the efficacy of the novel TP antagonist NTP42 in an MCT-induced PAH rat model. Throughout these preclinical investigations, the PAH standard-of-care drugs Sildenafil, a cGMP-specific phosphodiesterase type 5 (PDE5) inhibitor, and Selexipag, an oral prostacyclin receptor agonist, were used as reference controls.
The key pulmonary and cardiac haemodynamic findings are presented for each of the treatment groups in Figure 2. Significant MCT-induced PAH was evidenced by increases in both the mean pulmonary arterial pressure (mPAP; compare 28.5 ± 1.0 mmHg in the ‘MCT Only’-treated group to 15.5 ± 0.3 mmHg for the ‘No MCT’ group, P < 0.0001; Figure 2A) and right ventricular systolic pressure (RVSP; compare 44.7 ± 2.2 mmHg in the ‘MCT Only’-treated group to 26.1 ± 0.4 mmHg for the ‘No MCT’ group, P < 0.0001; Figure 2B) without any significant change observed in either the mean systemic arterial pressure (mAP; Figure 2D) or heart rate (HR; Figure 2E). In addition, significant right ventricular remodelling was observed by the increase in the Fulton’s index (right ventricle weight:left ventricle including the septum weight ratio; compare 0.30 ± 0.01 in the ‘MCT Only’-treated group to 0.21 ± 0.01 for the ‘No MCT’ group, P < 0.0001; Figure 2C).
Following treatment with NTP42, the MCT-induced increase in the mPAP was significantly reduced (compare 18.7 ± 0.9 mmHg in the NTP42-treated group to 28.5 ± 1.0 mmHg for the ‘MCT Only’ group, P < 0.0001; Figure 2A). Similarly, the MCT-induced increase in RVSP was significantly reduced in NTP42-treated animals (compare 36.6 ± 2.5 mmHg in the NTP42-treated group to 44.7 ± 2.2 mmHg for the ‘MCT Only’ group, P = 0.0229; Figure 2B). There was no significant change observed in the Fulton’s Index following NTP42 treatment (Figure 2C). Similar to NTP42, both standard-of-care drugs Sildenafil and Selexipag also significantly reduced the MCT-induced increases in mPAP (P < 0.0001 and P = 0.0003, respectively; Figure 2A). However, in contrast to both NTP42 and Sildenafil, treatment with Selexipag did not lead to a significant reduction in the RVSP (P = 0.0985; Figure 2B). Furthermore, while Sildenafil treatment led to a slight improvement in the Fulton’s Index (P = 0.0332; Figure 2C), a significant worsening in this parameter was observed following Selexipag administration (P = 0.0224; Figure 2C).
Taken together, these data demonstrate that NTP42 reduced the severity of MCT-induced PAH as determined from the haemodynamic measurements of mPAP and RVSP, and at least to a similar or greater extent relative to standard-of-care drugs Sildenafil or Selexipag. Importantly, while treatment with NTP42 reduced MCT-induced increases in both mPAP and RVSP, it had no deleterious effects on either the systemic mAP or HR (Figure 2D & E), similar to the standard-of-care drugs tested.
Effect of NTP42 on pulmonary vascular remodelling in the MCT-PAH rat model
As stated, vascular remodelling of small pulmonary arterioles is a key feature of PAH, including in the MCT preclinical model of PAH, being a key underlying aetiology that culminates in the elevated pulmonary arterial pressure characteristic of advanced PAH in humans.
Representative histology images showing the morphological changes in the lung tissue from the animal groups in the MCT-PAH model, including vascular remodelling of the arterioles, are shown in Figure 3. In animals within the ‘No MCT’ group, the lung tissue appears generally healthy. Specifically, animals within this group display a loose, open network of lung tissue with normal alveolar wall thickness (Figure 3A). There is no significant vascular remodelling apparent in the small and medium pulmonary arterioles and there are no apparent sites of appreciable inflammatory infiltration (Figure 3B). In contrast, animals within the ‘MCT Only’ group present with heavily diseased lung tissue. In these animals, the lung tissue is extremely dense in many regions with heavily thickened gas exchange distances apparent (Figure 3A). There is a high degree of vascular thickening present, particularly in small and medium vessels, and there are multiple large instances of inflammation and oedema apparent (Figure 3B).
Similarly, within the Sildenafil- and Selexipag-treated animals, the lung tissue also appears quite diseased (Figure 3). While the tissues from these animals is generally loose and open, there are multiple dense pockets with heavily thickened gas exchange distances present (Figure 3A). There are also varying degrees of vascular remodelling apparent, in addition to small pockets of inflammation dispersed throughout the sections from these animals (Figure 3B). In contrast, lung tissue from NTP42-treated animals appeared substantially less diseased (Figure 3). Reminiscent of findings from the ‘No MCT’- group, NTP42-treated animals displayed a loose, open network of lung tissue with normal alveolar wall thickness (Figure 3A). In these NTP42-treated animals, there was a very low degree of vascular remodelling present with only small numbers of sites of substantial inflammatory infiltration present (Figure 3B).
In order to quantify the observed extent of vascular remodelling, detailed morphometric analyses of the pulmonary arterioles in lung tissues was performed across all animals and treatment groups. These morphometric analyses confirmed that MCT treatment led to substantial worsening relative to the ‘No MCT’ animal group in the three parameters reported by this approach, namely, lumen:total vessel diameter ratio, medial thickness, and degree of vessel occlusion (Figure 4). Notably, this significant vascular remodelling was observed in groupings of either all vessels > 15 μm in size (P < 0.0001, P = 0.0002 and P < 0.0001, respectively; Figures 4A-C) or in a grouping of small (> 15 μm and ≤ 50 μm) pulmonary arterioles only (all P < 0.0001; Figures 4D-F).
Treatment with NTP42 significantly attenuated both the MCT-induced decrease in lumen:total vessel diameter ratio and the MCT-induced increase in the degree of vessel occlusion (P < 0.0001, in all cases; Figures 4A & C). Similarly, treatment with Sildenafil also led to improvements in these parameters relative to the ‘MCT Only’ control (P = 0.0152 and P = 0.0148, respectively; Figures 4A & C). Improvements in these pulmonary vascular remodelling parameters were also observed for both NTP42- and Sildenafil-treated animals in small vessels only (Figures 4D & F). Notably, while showing a varying degree of improvement, treatment with Selexipag did not lead to significant changes in either the lumen:total vessel diameter ratio or the degree of vessel occlusion, relative to the ‘MCT Only’ controls (P = 0.3976 and P = 0.3873, respectively; Figures 4A & C).
In parallel and consistent with these effects, morphometric analysis also confirmed that the MCT-induced increase in the medial thickness of pulmonary arterioles was significantly reduced in MCT-treated animals following treatment with NTP42 (P < 0.0001), but not following treatment with either Sildenafil or Selexipag (Figures 4B & E). Moreover, the medial thickness observed following treatment with NTP42 was significantly reduced relative to both Sildenafil- and Selexipag-treated animals (P = 0.0302 and P = 0.0018, respectively; Figure 4B).
Hence, these data strongly support the efficacy of NTP42 in reducing pulmonary vascular remodelling, and that it is superior to Sildenafil in bringing about these effects, clearly highlighting the potential significant benefits of NTP42 relative to the standard-of-care reference drugs Sildenafil or Selexipag.
Effect of NTP42 on pulmonary inflammation and fibrosis
There is growing evidence of the diverse role for inflammatory processes and cell-mediated immunity in the pathogenesis of PAH and indeed other pulmonary conditions(23). Of the various immune cells that have been implicated in PAH, mast cells were among the first suggested to potentially play a key role in its pathophysiology, strongly contributing to vascular remodelling and leading to pulmonary fibrosis. As such, modulators of mast cells and mast cell-derived mediators may present promising targets for the treatment of lung diseases such as PAH(24). To evaluate the effect of NTP42 treatment on mast cell recruitment and the development of pulmonary fibrosis, lung tissues were stained with toluidine blue and Masson’s trichrome to quantity mast cell density and determine collagen deposition, respectively. Results are shown in Figure 5.
After staining with toluidine blue, lung sections from animals in the ‘MCT Only’ group showed a significantly elevated mast cell density relative to those from the ‘No MCT’ group (P < 0.0001; Figure 5A). Similarly, after staining with Masson’s trichrome, the percentage fibrotic area in the lungs of animals treated with ‘MCT Only’ was significantly increased compared to those from the ‘No MCT’ group (P = 0.0040; Figure 5B). As displayed in representative photomicrographs in Figure 5C & D, mast cell recruitment and pulmonary fibrosis in the ‘MCT Only’ group were most pronounced in the immediate vicinity of small pulmonary arterioles.
Treatment with NTP42 significantly attenuated both the MCT-induced increase in mast cell density and percentage fibrotic area (P = 0.0002 and P = 0.0180, respectively; Figures 5A & C). Notably, of the treatments assessed in this study, NTP42 was the only agent that led to significant and substantial decreases in these parameters. In contrast, treatment with either Sildenafil or Selexipag produced less noticeable changes in the MCT-induced increase in mast cell density and percentage fibrotic area within the lungs of animals treated with these compounds (Figures 5A & C).
Representative photomicrographs in Figure 5C & D, with a focus around vascular beds, show a noticeably more pronounced mast cell recruitment and collagen deposition in animals treated with either Sildenafil or Selexipag, compared to those in the NTP42-treated group. Furthermore, and in line with the histological assessments and morphometric analyses performed previously (Figures 3 & 4), pulmonary vascular remodelling in NTP42-treated animals appears noticeably reduced relative to the ‘MCT Only’ controls, and indeed relative to the Sildenafil- and Selexipag-treated animal groups.