Toll-Like Receptor Signalling Pathways Regulate Hypoxic Stress Induced Fibroblast Growth Factor but Not Vascular Endothelial Growth Factor-A in Human Microvascular Endothelial Cells

: Retinal diseases are the leading causes of irreversible blindness worldwide. The role of toll-like receptor (TLR) signalling mechanisms (MyD88 and TRIF) in the production of pro-angiogenic growth factors from human microvascular endothelial cells (HMEC-1) under hypoxic stress remains unexplored. HMEC-1 was incubated under normoxic (5% CO 2 at 37 ◦ C) and hypoxic (1% O 2 , 5% CO 2 , and 94% N 2 ; at 37 ◦ C) conditions for 2, 6, 24, and 48 h, respectively. For TLR pathway analysis, HMEC-1 was pre-treated with pharmacological inhibitors (Pepinh-MyD88 and Pepinh-TRIF) and subjected to normoxia and hypoxia conditions. Gene and protein expressions of vascular endothelial growth factor-A (VEGF-A), ﬁbroblast growth factor (FGF-2), hypoxia inducible factor 1-alpha (HIF1- α ) were performed using quantitative polymerase chain reaction (qPCR), ELISA, and Western blot methodologies. Levels of TLR3 and TLR4 were analysed by ﬂow cytometry. Under hypoxia, levels of VEGF-A and FGF-2 were elevated in a time-dependent fashion. Inhibition of MyD88 and TRIF signalling pathways decreased FGF-2 levels but failed to modulate the secretion of VEGF-A from HMEC-1. Blocking a known regulator, endothelin receptor (ETR), also had no effect on VEGF-A secretion from HMEC-1. Overall, this study provides the proof-of-concept to target TLR signalling pathways for the management of blinding retinal diseases.


Introduction
Vision is paramount for healthy ageing, and its impairment or loss is considered a major disability. Retinal diseases such as age-related macular degeneration (AMD) and diabetic retinopathy (DR), including diabetic macular oedema (DMO), are the leading causes of irreversible blindness worldwide [1]. AMD is a progressive neurodegenerative disease of the retina, which is clinically sub-divided into two forms: dry (geographic atrophy-GA) and wet (neovascular-nAMD). It is highly prevalent in individuals above 60 years of age and accounts for approximately 8.7% of all blindness [2]. DR, with DMO or proliferative DR (PDR), is highly prevalent in the working-age population and commonly affects individuals that are suffering from long-standing diabetes mellitus [1]. DMO, PDR, and nAMD are characterised by increased vascular permeability resulting in macular oedema and/or neovascularisation, with haemorrhage in retinal and vitreous space, fibrotic scarring, and traction retinal detachment. Inflammation and hypoxia/ischaemia are the two main pathophysiological determinants of retinal and choroidal vascular abnormalities that are associated with these diseases [1].
Hypoxia is a condition in which oxygen tension is adequately deficient at tissue level, this then upregulates cellular expression of hypoxia-inducible factor-1α (HIF1-α) [3]. HIF1α regulates the synthesis and release of angiogenic factors such as fibroblast growth factor (FGF-2) and VEGF-A [4]. Hypoxia-activated endothelin-1/endothelin receptor signalling has been implicated in VEGF-A production from macrovascular endothelial cells and melanoma cells [5]. Moreover, increased plasma levels of endothelin-1 have been associated with the risk of nAMD [6]. Thus far, the underlying mechanisms of pathophysiology of hypoxia-mediated microvascular angiogenesis/proliferation and resultant fibrotic scarring remain elusive.
Toll-like receptors (TLRs) are a distinct family of transmembrane pattern-recognition receptors that are expressed on a variety of ocular tissues and cells and have been associated with a number of vascular and inflammatory diseases [7][8][9]. TLR3 has been shown to be present on RPE, retinal and choroidal endothelial cells [7,10]. Ligand activation of TLR3 in RPE cells increases Toll/interleukin-1 receptor (TIR) domain-containing adaptor protein-inducing interferon-β (TRIF) dependent secretion of VEGF and reduction in RPE viability [11]. Mouse models deficient in TLR3 showed augmented laser-induced neovascularization [12,13], while loss-of-function polymorphism of TLR3 gene in humans has been reported to be protective against dry AMD [14,15]. Thus far, the role of TLR3 on vascular endothelial cells during hypoxic stress remains unexplored. TLR4 mediates its downstream signalling through both myeloid differentiation factor 88 (MyD88), as well as TRIF-dependent signalling pathways [16]. Our laboratory was first to demonstrate the expression of TLR4 on primary retinal and choroidal vascular endothelial cells [7]. Previous studies have implicated the role of TLR4 in retinal damage caused by ischaemia and PDR [17,18]. In addition, TLR4 was shown to participate in phagocytosis of photoreceptor outer segments by the RPE [19,20]. These findings suggest that TLR4 on RPE and photoreceptors cells has a crucial role in retinal ischaemic injury. However, the role of TLR4 on microvascular endothelium during ischaemic injury is still not clearly understood.
In this study, we aimed to establish the role of MyD88 and TRIF signalling pathways on production of VEGF-A and FGF-2 from the human microvascular endothelial cells, as a model for retinal microvascular endothelium, during normoxia and hypoxia. We have also validated the role of ETR in regulation of VEGF-A in HMEC-1 during hypoxia. As there may be significant exposure of donor eyes to post-mortem hypoxia preceding isolation of human retinal and choroidal endothelial cells (hREC and hCEC), and in order to allow for such potential variability in hypoxia exposure in the primary isolated hCEC, human microvascular EC lines (HMEC-1) were used for a significant part of this study after establishing their TLR expression as similar to that of hREC and hCEC. This study extends our previous reports on the signalling mechanisms in microvascular angiogenesis, and their relevance in intraocular, particularly retinal and choroidal ischaemia and neovascularisation. Here, we demonstrated that hypoxia-activated signalling pathways in HMEC-1 are regulated through TLRs.

Materials and Methods
The research was complied with the institutional regulations of good laboratory practice (GLP) and Health and Safety guidelines of the University of Nottingham. Aseptic conditions were followed in all experiments, which were performed within the laminar flow air hood (Envair, Rossendale, UK).

Cell Viability Assay
HMEC-1 viability was determined using cell counting kit-8 (CCK-8) (Sigma-Aldrich, Gillingham, UK). Then, 1.5 × 10 4 cells were seeded into each well of four individual 96-well plates and incubated at 37 • C, 5% CO 2 . Following overnight starvation, plates were incubated under normoxic and hypoxic conditions for different durations. At the end of each incubation, 10 µL CCK-8 was applied into each well and further incubated for 2 h. Viable cells converted the WST-8 dye into formazan, which was measured at optical density 450 nm using the CLARIOstar Microplate-reader (BMG LABTECH, Ortenberg, Germany).

Total RNA Isolation
Total RNA was extracted according to manufacturer's protocol (RNeasy mini kit; Qiagen, Manchester, UK). Following treatment, HMEC-1 was lysed with 650 µL RLT lysis buffer (Qiagen, Manchester, UK) and homogenised using QIAshredder column. The lysate was then mixed with equal volume of 70% ethanol. The mixture was applied into new nucleic acid binding-column and centrifuged at 10,000× g for 15 s. The filtrate was discarded, and spin columns were washed with buffers RW1 and RPE (Qiagen, Manchester, UK), respectively, by centrifugation. Total RNA was eluted in RNase-free water and quantified using CLARIOstar Microplate-reader (BMG LABTECH, Ortenberg, Germany).

Reverse Transcription into Complementary DNA (cDNA)
Using a commercial kit (Quantitect Reverse Transcription kit; Qiagen, Manchester, UK), total RNA (1 µg) was reverse transcribed into cDNA. Total RNA was mixed with genomic DNA wipeout buffer (Qiagen, Manchester, UK) and incubated at 42 • C for 2 min. The mix was placed on ice, and then buffered reverse transcriptase (Quantitect Reverse Transcriptase, RT Buffer, and RT Primer mix; Qiagen, Manchester, UK) was added. The final mix was incubated for 30 min at 42 • C for cDNA synthesis. This was followed by a reverse transcriptase deactivation step for 3 min at 95 • C. cDNA samples were then stored at −20 • C until further analysis.

Quantitative Polymerase Chain Reaction (qPCR)
QPCR analysis of the desired gene of interest was performed using inventoried Taq-Man probe chemistry (Table 1) (ThermoFisher Scientific, Waltham, MA, USA) as previously described [21]. The qPCR reactions were run in an 8-strip optical tubes (Starlab (UK) Ltd., Milton Keynes, UK) using Taqman gene expression mastermix in the Mx3005p real-time PCR instrument (Agilent Technologies, Cheshire, UK) as detailed in the manufacturers protocol (ThermoFisher Scientific, Waltham, MA, USA). Briefly, template cDNA was diluted 1 in 5 with nuclease-free water to perform qPCR in duplicate. Each reaction was prepared to 20 µL final reaction volume containing 15 µL of PCR reaction mix and 5 µL of diluted cDNA template. Each 8-strip tube was run with a Taqman probe/primer mix for the gene of interest and endogenous controls (Table 1). Appropriate negative non-template controls were also run. Samples were loaded and run under appropriately set experimental settings and PCR thermal cycling conditions recommended by the manufacturer. Data were acquired on the MxPro Software (version 4.01, Stratagene, Cambridge, UK) and transferred to a Microsoft Excel spreadsheet for analysis using the delta-delta CT comparative quantitation method.

ELISA
The concentrations of VEGF-A and FGF-2 protein in the conditioned culture media was determined using ELISA as previously described [22]. Human VEGF-A and FGF2 DuoSet ELISA kits were supplied by R&D Systems (Minneapolis, MN, USA). ELISA plates were coated overnight with the working concentrations of capture antibody (VEGF-A: 1 µg/mL or FGF-2: 2 µg/mL) at room temperature. Plates were washed six times with Wash Buffer, blocked with Reagent Diluent (1% BSA in 1× PBS) and incubated for 1 h at room temperature. Washing steps were repeated and culture media was centrifuged at 1000 g for 5 min. Recombinant standards (at different concentrations) and samples (1 in 2 diluted) were incubated for 2 h at room temperature. ELISA plates washed and incubated with working concentrations of detection antibody (Biotin conjugated anti-human VEGF-A: 100 ng/mL) or (Biotic conjugated anti-human FGF2: 250 ng/mL) for 2 h at room temperature. After washing step, 100 µL of working dilution of streptavidin-HRP (40-fold dilution) was added to each well and incubated for 20 min in the dark. The plates were washed, and 100 µL of substrate solution (1:1 mixture of Colour Reagent A and B) was added to each well and incubated at room temperature for 20 min in the dark. The colour development was stopped using 50 µL of stop solution, and optical density was determined using CLARIOstar Microplate-reader (BMG LABTECH, Ortenberg, Germany) at 450 nm and corrected with 540 nm. The data were analysed by 4-parameter linear regression method.

Protein Estimation for Immunoblotting
Total protein was extracted from treated HMEC-1 using Urea lysis buffer containing 5% V/V glycerol, 10 mM Tris (pH 6.8), 0.05% W/V sodium dodecylsulfate (SDS) and 1 mM β-mercaptoethanol. The lysate was collected by centrifugation at 1000 g for 5 min at 4 • C. Protein concentrations were then determined with BCA Protein Assay Kit (Pierce; ThermoFisher Scientific, Waltham, MA, USA) according to manufacturer's instructions at 562 nm optical density using CLARIOstar Microplate-reader (BMG LABTECH, Ortenberg, Germany).

Western Blot
Western blotting was performed as previously described [23]. Protein extracts were mixed with 4× SDS sample buffer and incubated for 3 min at 95 • C. Protein samples (100 µg) were separated using precast 4-12% NuPAGE gel and blotted onto a PVDF membrane.

Data Analysis
Data were expressed as mean ± standard deviation (SD) of three biological replicates from each of two independent experiments. Statistical analysis of data was achieved using statistical software, GraphPad Prism version 7.0 (GraphPad Software Inc., San Diego, CA, USA). Alpha was set at p = 0.05, and different groups were analysed using two-way ANOVA.

Effect of Hypoxia on HMEC-1 Viability
As a first step, we assessed the effect of hypoxia on viability of HMEC-1 for different durations (24 and 48 h). As shown in Figure 1, no significant decrease in HMEC-1 viability was detected at 24 h under hypoxia. However, a 54% reduction in cell viability (p ≤ 0.0001) was observed following 48 h of hypoxic stress compared to cells incubated in normoxic conditions. durations (24 and 48 h). As shown in Figure 1, no significant decrease in HM was detected at 24 h under hypoxia. However, a 54% reduction in cell viabili was observed following 48 h of hypoxic stress compared to cells incubated conditions.

Hypoxia Treatment Modulates mRNA Expression of Growth Factors, HIF1-α, Receptors
We aimed to assess the longitudinal effect of hypoxic stress on mRNA  Figure 2C) showed reduced expression poxic stress compared to normoxia. However, after 24 h of hypoxic stress, H was modestly elevated with significant increase noted at 48 h (1.60  0.15 fold As shown in Figure 2D, TLR3 mRNA levels did not change significantly u until 24 h. Notably, at 48 h, TLR3 mRNA was reduced by more than 90% ( hypoxic samples. In stark contrast, TLR4 mRNA ( Figure 2E) was increased 0.53 folds) and sustained until 48 h of hypoxic stress (4.0  0.73 folds, p  0.0

Effect of Hypoxia on VEGF-A and FGF-2 Secretion from HMEC-1
Next, we quantitated the secretion of VEGF-A and FGF-2 protein from HMEC-1 under hypoxia for different durations. As shown in Figure 3A, VEGF-A protein was not secreted in normoxic conditions. Under hypoxia, a time-dependent increased secretion of VEGF-A starting 6 h was noted. After 48 h of hypoxia challenge, VEGF-A protein was increased and found to be 114 ± 43.25 pg/mL. Correspondingly, FGF-2 was released at normal levels in supernatants of HMEC-1 under normoxic conditions ( Figure 3B). Until 24 h of hypoxia, FGF-2 was secreted at basal levels. Notably, at 48 h duration, the levels increased significantly to 200 ± 89.86 pg/mL; p = 0.0008.

Effect of Hypoxia on VEGF-A and FGF-2 Secretion from HMEC-1
Next, we quantitated the secretion of VEGF-A and FGF-2 protein from HMEC-1 under hypoxia for different durations. As shown in Figure 3A, VEGF-A protein was not secreted in normoxic conditions. Under hypoxia, a time-dependent increased secretion of VEGF-A starting 6 h was noted. After 48 h of hypoxia challenge, VEGF-A protein was

Hypoxia Modulates Protein Expression of TLR3, TLR4 and HIF1-α in HM
We examined the effect of hypoxic stress on intracellular levels of T 24 and 48 h time-points using flow cytometry. After 24 h under hypoxia in TLR3 levels was noted in HMEC-1 ( Figure 4A). However, TLR4 leve changed ( Figure 4C). Notably, after 48 h of hypoxic stress, both TLR3 TLR4 ( Figure 4D) intracellular levels were elevated. We did not observe for TLR3 and TLR4 on extracellular surface of normoxic or hypoxic HM shown). As shown in Figure 5, signal intensity of HIF1-α was increased b and remained elevated up to 24 h (p = 0.0096) of hypoxia. However, in n 1 lysates, we did not observe a positive protein band signal for HIF1-α. T trol, -actin, was used to normalise the signal intensity.

Hypoxia Modulates Protein Expression of TLR3, TLR4 and HIF1-α in HMEC-1
We examined the effect of hypoxic stress on intracellular levels of TLR3 and TLR4 at 24 and 48 h time-points using flow cytometry. After 24 h under hypoxia, a mild increase in TLR3 levels was noted in HMEC-1 ( Figure 4A). However, TLR4 levels remained unchanged ( Figure 4C). Notably, after 48 h of hypoxic stress, both TLR3 ( Figure 4B) and TLR4 ( Figure 4D) intracellular levels were elevated. We did not observe positive staining for TLR3 and TLR4 on extracellular surface of normoxic or hypoxic HMEC-1 (data not shown). As shown in Figure 5, signal intensity of HIF1-α was increased by 6 h (p = 0.0004) and remained elevated up to 24 h (p = 0.0096) of hypoxia. However, in normoxic HMEC-1 lysates, we did not observe a positive protein band signal for HIF1-α. The loading control, β-actin, was used to normalise the signal intensity.      The signal intensity was semi-quantitatively normalised against actin using ImageJ software (NIH). All data represented as mean ± SD of three independent experiments. The corresponding strips have been cropped in order to improve the clarity and conciseness of presentation.

TRIF Activation Pathway Plays a Key Role in Induction of VEGF-A and FGF-2 under Hypoxia
To study the role of TLR signalling pathways in regulation of VEGF-A and FGF-2 secretion under hypoxia, we pre-treated HMEC-1 with pharmacological inhibitor peptides against MyD88 (Pepinh-MYD; 40 µM) and TRIF (Pepinh-TRIF; 30 µM) for 6 h prior to hypoxic stress for 48 h. As shown in Figure 6A, MyD88 pathway inhibition did not affect the VEGF-A levels under hypoxia. Blocking TRIF pathway significantly reduced VEGF-A (up to 25%) compared to vehicle pre-treatment (29.83 ± 3.92 pg/mL; p = 0.0104). Unlike VEGF-A, inhibition of MyD88 has markedly decreased FGF2 production (90.0 ± 20.44 SD pg/mL; p = 0.0129) with levels matching basal FGF2 release from normoxic HMEC-1 ( Figure 6B). Similarly, inhibition of TRIF pathway prior to hypoxia also reduced FGF2 levels significantly (90.1 ± 29.24 SD pg/mL; p = 0.0129).

TRIF Activation Pathway Plays a Key Role in Induction of VEGF-A and FGF-2 under Hypoxia
To study the role of TLR signalling pathways in regulation of VEGF-A and FGF-2 secretion under hypoxia, we pre-treated HMEC-1 with pharmacological inhibitor peptides against MyD88 (Pepinh-MYD; 40 μM) and TRIF (Pepinh-TRIF; 30 μM) for 6 h prior to hypoxic stress for 48 h. As shown in Figure 6A, MyD88 pathway inhibition did not affect the VEGF-A levels under hypoxia. Blocking TRIF pathway significantly reduced VEGF-A (up to 25%) compared to vehicle pre-treatment (29.83  3.92 pg/mL; p = 0.0104). Unlike VEGF-A, inhibition of MyD88 has markedly decreased FGF2 production (90.0  20.44 SD pg/mL; p = 0.0129) with levels matching basal FGF2 release from normoxic HMEC-1 ( Figure 6B). Similarly, inhibition of TRIF pathway prior to hypoxia also reduced FGF2 levels significantly (90.1  29.24 SD pg/mL; p = 0.0129).

Role of Endothelin Receptor in Regulation of VEGF-A and FGF-2 Production
Previous studies have shown that endothelin receptor (ETR) regulates VEGF-A secretion from a variety of cell types under hypoxia [5,24]. As a first step to extend our understanding of VEGF-A and FGF-2 production under hypoxia from microvascular HMEC-1 cells, we blocked total protein synthesis. Treatment with cycloheximide (CHX) at 100 μM for 24 h prior to hypoxia was shown to block the production of VEGF-A ( Figure  7A) and FGF-2 ( Figure 7B). Next, we examined the effect of ETR antagonist, BQ123, on VEGF-A and FGF-2 production in response to hypoxia. VEGF-A levels did not change following treatment with BQ123 ( Figure 7A). In contrast, FGF-2 levels declined following inhibition of ETR ( Figure 7B).

Role of Endothelin Receptor in Regulation of VEGF-A and FGF-2 Production
Previous studies have shown that endothelin receptor (ETR) regulates VEGF-A secretion from a variety of cell types under hypoxia [5,24]. As a first step to extend our understanding of VEGF-A and FGF-2 production under hypoxia from microvascular HMEC-1 cells, we blocked total protein synthesis. Treatment with cycloheximide (CHX) at 100 µM for 24 h prior to hypoxia was shown to block the production of VEGF-A ( Figure 7A) and FGF-2 ( Figure 7B). Next, we examined the effect of ETR antagonist, BQ123, on VEGF-A and FGF-2 production in response to hypoxia. VEGF-A levels did not change following treatment with BQ123 ( Figure 7A). In contrast, FGF-2 levels declined following inhibition of ETR ( Figure 7B).

Discussion
Hypoxia is known to induce TLRs in a variety of cell types including macrophages, dendritic cells and some cancer cells [25,26]. Numerous studies utilising macrovascular ECs have associated the role of TLRs in hypoxia-mediated angiogenic responses [27][28][29]. Our group has previously demonstrated that there are significant differences between microvascular REC and CEC, and macrovascular HUVEC [30]. In a subsequent study, we demonstrated the constitutive expression of TLRs in primary human retinal and choroidal ECs. More importantly, we established that the expression pattern and localisation of TLRs significantly differ between naïve primary microvascular (REC and CEC) and macro-vascular ECs [7]. As such, there are significant gaps in our understanding of the mechanisms of TLR stimulation in ocular vascular endothelial cells, particularly, their role in CEC survival (or apoptosis) and/or proliferation in AMD. This study provides evidence that hypoxia causes significant modulation of angiogenic growth factors (VEGF-A and FGF-2), HIF-1α, and TLRs in microvascular endothelial cells.
A central role of the TLR-signalling in the regulation of innate immune response, as well as a key regulator of hypoxia in angiogenesis, and the transcriptional effects of hypoxia on TLRs have been previously described [31]. Significantly, Basu et al. described induction of TLR4 and 2 in association with downstream signalling under hypoxia [32]. Recently, TLR3 has been reported to be protective in arterial wall endothelium [33]. Similar protection was demonstrated for synthetic TLR3 ligand (Poly I:C, especially in high doses) and thought to be mediated through anti-inflammatory cytokine, IL-10 [33,34]. Furthermore, TLR3 deficiency is reported to promote EC apoptosis and increased expression of IL-6 and ET-1, but not IL-10 [35], suggesting a dysregulation of RNA expression or sensing resulting from reduced TLR3 expression. However, these previous investigations utilised macrovascular endothelial cells, including arterial cells [33], stellate or Kupffer cells in the liver [34].
Both TLR3 and TLR4 have been implicated in DR [36] and retinopathy of prematurity (ROP) [37] through stimulation of varying cytokines. Genetic mutations in TLR4 have also

Discussion
Hypoxia is known to induce TLRs in a variety of cell types including macrophages, dendritic cells and some cancer cells [25,26]. Numerous studies utilising macrovascular ECs have associated the role of TLRs in hypoxia-mediated angiogenic responses [27][28][29]. Our group has previously demonstrated that there are significant differences between microvascular REC and CEC, and macrovascular HUVEC [30]. In a subsequent study, we demonstrated the constitutive expression of TLRs in primary human retinal and choroidal ECs. More importantly, we established that the expression pattern and localisation of TLRs significantly differ between naïve primary microvascular (REC and CEC) and macrovascular ECs [7]. As such, there are significant gaps in our understanding of the mechanisms of TLR stimulation in ocular vascular endothelial cells, particularly, their role in CEC survival (or apoptosis) and/or proliferation in AMD. This study provides evidence that hypoxia causes significant modulation of angiogenic growth factors (VEGF-A and FGF-2), HIF-1α, and TLRs in microvascular endothelial cells.
A central role of the TLR-signalling in the regulation of innate immune response, as well as a key regulator of hypoxia in angiogenesis, and the transcriptional effects of hypoxia on TLRs have been previously described [31]. Significantly, Basu et al. described induction of TLR4 and 2 in association with downstream signalling under hypoxia [32]. Recently, TLR3 has been reported to be protective in arterial wall endothelium [33]. Similar protection was demonstrated for synthetic TLR3 ligand (Poly I:C, especially in high doses) and thought to be mediated through anti-inflammatory cytokine, IL-10 [33,34]. Furthermore, TLR3 deficiency is reported to promote EC apoptosis and increased expression of IL-6 and ET-1, but not IL-10 [35], suggesting a dysregulation of RNA expression or sensing resulting from reduced TLR3 expression. However, these previous investigations utilised macrovascular endothelial cells, including arterial cells [33], stellate or Kupffer cells in the liver [34].
Both TLR3 and TLR4 have been implicated in DR [36] and retinopathy of prematurity (ROP) [37] through stimulation of varying cytokines. Genetic mutations in TLR4 have also been implicated in DR development [38]. Ishida et al. reported that long-term hypoxia reduced TLR stimulation of endothelial cells [39], whilst hypoxia exposure of macrophages increased TLR4 expression [25]. Some reports have suggested that the early phase of inflammatory response in ischaemia was mediated through MyD88 signalling, whilst the TRIF signalling effect was important in the late phase [40].
We investigated MyD88 and TRIF explicitly, rather than each individual TLR, as these adaptors together cover the signalling pathways of all TLRs. TLR3 utilises TRIF only, whilst TLR4 signals through MyD88 and TRIF. Inhibition of the MyD88 pathway had an insignificant effect on VEGF-A secretion in hypoxia, whilst there was only a minimal reduction in VEGF-A secretion following TRIF signalling blockage. On the other hand, inhibition of both TRIF and MyD88 signalling decreased FGF-2 production in HMEC-1, confirming that FGF-2 induction is mediated through a different mechanism from VEGF-A.
Levels of HIF-1α in HMEC-1 under hypoxia were consistent with a previous report that described HIF-1α-dependent regulation of FGF-2 in muscle cells under hypoxia [41]. Our findings have clearly demonstrated the redundant function of HIF-1α in HMEC-1 under hypoxia because blocking TLR signalling mechanisms (key regulators of HIF-1α activity in hypoxic macrovascular ECs) inhibited FGF-2 but not VEGF-A production. This warrants further characterisation or validation of HIF-1α function in microvascular ECs under hypoxia. Recent reports have indicated the specific role of endothelin receptor (ETR) in VEGF secretion from the macrovascular endothelial cells (HUVEC) and other cancer cells under hypoxia [5,24]. Additionally, a relation between elevated serum ET-1 levels and nAMD has been reported [6]. Unlike previous studies, our results demonstrated for the first time that the ETR plays a redundant role in regulation of VEGF-A in HMEC-1. Instead, FGF-2 was found to be regulated through ETR in HMEC-1.
The main limitation of this study is that it utilised HMEC-1 cells. However, the results from this study are more applicable to retinal and choroidal vasculature, which consist of microvascular endothelial cells similar to the HMEC-1 used in this study, unlike HUVEC. Further studies with human REC and CEC are required for validation. Although hypoxia has been shown to regulate TLR-mediated angiogenic growth factors, it is still unclear how TLRs are activated under hypoxia. DAMPS have been shown to activate TLRs in a variety of cell types [42]. A possibility is that hypoxia-triggered EC damage may release DAMPS with subsequent TLR activation [43]. Further studies will elucidate this intriguing phenomenon of feedback activation loop.
The findings from this study indicate that blockage of VEGF-A and FGF-2 pathways may lead to complementary effects in the modulation and treatment of retinal ischaemic diseases. This is underscored by the fact that, in clinical practice, a significant number of eyes receiving anti-VEGF therapies for retinal vascular diseases (including nAMD, and DR) show suboptimal response.  Conflicts of Interest: W.M.A.: commercial relationships: acted as consultant for Abbvie, Alimera, Allergan Inc, Bayer, Novartis, Pfizer, Santen and Thrombogenics, and has undertaken research sponsored by Allergan, Bayer, Boerhinger Ingelheim, Novartis and Pfizer. He has received speaker fees and travel grants from Allergan, Bausch and Lomb, Bayer, Novartis and Pfizer. All other authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.