Healing is a complex cascade of events that are not clearly separated, but they interfere and involve complex interactions of different cell types, mediators, cytokines, and the vascular system. Briefly, tissue healing is a procedure during which growth factors cause cell proliferation, leading to the integration of dynamic changes involving soluble mediators, blood cells, extracellular matrix production, and parenchymal cell proliferation. We can distinguish several phases of healing: hemostasis, inflammatory phase, proliferative phase and maturation phase. One of the earliest responses to injury results from damage to blood vessels in the wound area. Blood coagulation is enabled by various humoral and cellular ingredients such as fibrinogen and platelets which are also responsible for signaling that contributes healing. Various cytokines (chemokines, interleukins, interferons, TNF, etc.) and growth factors (PDGF, VEGF, TGF-β, etc.) are released. They are signals for regrutation of circulating inflammatory cells to the wound site, they initiate reepithelialization and connective tissue contraction, stimulate keratinocyte and fibroblast migration and stimulate the angiogenic response. Inflammatory cells like neutrophiles and macrophages are attracted to the wound site where they phagocytise debris, release NO (increase vascular permeability) and reactive oxygen species – ROS (killing pathogens), secreting proteases (break down damaged cells), produce and release cytokines, angiogenic, inflammatory and fibrogenic factors. Epidermis and dermis are regenerated by migration and proliferation of different cells near the lesion as keranocytes and fibroblasts. For successful wound reparation, it is necessary to ensure the transport of fluid, nutrients, oxygen and immunocompetent cells to the newly formed tissue, so the development of new blood vessels is essential. Angiogenesis is a complex process involving the proliferation, migration and remodeling of endothelial cells as well as pericyte stabilization. These events are regulated by multiple cytokines and growth factors. Binding of growth factors to their receptors induce receptor dimerization which activates receptor kinases, receptor autophosphorylation and downstream signalling (PI3K-AKT-eNOS, RAS-RAF-MEK-ERK/MAPK, etc.). In the final stage of healing, it is necessary to establish a normal tissue structure and a scar is formed with a large number of collagen fibers. All these processes and events can be modulated by numerous exogenous and endogenous factors. Some of them will have negative effect (old age, infection, diabetes), but some of them can enhance wound healing. One of the agens that improves healing is synthetic pentadecapeptide – BPC 157. It is confirmed by a series of studies: different types of lesions (skin, muscle, tendon), burns, bone fractures, eye injuries, brain and spinal cord injuries digestive system impairments etc. In addition to healing, it also has a proven cellprotective and organoprotective effect. BPC 157 has no proven lethal dose and can be administrated without a carrier. The impact of BPC 157 on healing is reflected in rapid development of granulation tissue, its maturation and degradation, improved epithelialization and increased wound vascularization. The role of the NO-system is very important in the healing process, and the effect of BPC 157 on the NO system has been demonstrated in several studies (activation of VEGFR2-AKT-eNOS signaling pathway). BPC 157 stimulates the expression of several genes mRNA (Egr1, Nab2, Nos3, Cox2, Vegfa) and phosphorylation of proteins important for cell adhesion, proliferation and migration (Ptk2, Pxn, Akt1), all mechanisms important for angiogenesis. Although results of previous studies suggest promotional effect of BPC 157 on angiogenesis, the molecular level of this mechanism has not been fully elucidated. Aim of the study The aim of this study was to evaluate the effect of the peptide BPC 157 on early phase expression of the angiogenesis-related genes which was analyzed on the rat skin wound model. Also, to confirm the effect of BPC 157 on expression of these genes, to show its angiogenetic effect at the molecular level, to identify affected signaling pathways and to elucidate the action mechanism of BPC 157. Material and methods The study was performed on female Wistar albino rats. The animals were randomly assigned to two basic groups: control and treated with BPC 157, within which there were subgroups with different time intervals from wound induction and agens application to sampling. Excision wound was performed with a 5 mm diameter biopsy punch in the skin of the inner part of the hind right limb and immediate intraperitoneal administration of saline and solution of BPC 157 in saline (2 µg/mL), respectively, was done (10 µg/kg body weight). After two, five and 10 minutes, respectively, the wound was frozen locally and a ring-shaped skin and subcutaneous tissue sample was then taken around the wound using a round 8 mm diameter biopsy knife. Immediately after sampling, the tissue was frozen in liquid nitrogen and stored until RNA extraction. Prior to extraction of total RNA, tissue was homogenized. RNA extraction was done using the TRIzol-based method. The concentration of RNA samples was measured and a reverse transcription reaction was performed. Analysis of selected genes expression evaluated on mRNA level was done using the quantitative real-time polymerase chain reaction method (qRT-PCR). Obtained data revealed the potential activation of signaling pathways associated with angiogenesis and the mechanism of peptide BPC 157 activity, respectively. The ΔΔCt method was used to determine the relative quantification of gene expression, and results were presented as 2 -ΔΔCt values. Akt1, Braf, Egfr, Egr1, Grb2, Hdac7, Kras, Mapk1, Mapk3, Mapk14, Nos3, Pik3cd, Plcg1, Prkcg, Ptk2, Pxn, Src, Srf and Vegfa genes were analyzed. Endogenous controls, ie housekeeping genes Gapdh, Actb and Rn18s, were used for results normalization. Fold change with values < 1 was considered as reduced expression, while fold change > 1 indicated increased expression. The data obtained were analyzed, based on the distribution, by the Student's T-test, and the value of p < 0.05 was considered statistically significant. Results BPC 157 increases the expression of all investigated genes. Significant upregulation of Akt1, Grb2, Nos3, Pik3cd, Prkcg, Ptk2 and Src gene expression was noted after only two minutes, and can also be detected in five and 10 minutes time periods. As for the expression of Braf, Egfr, Egr1, Hdac7, Mapk1, Mapk3, Mapk14, Plcg1, Prkcg, Ptk2, Pxn, Srf and Vegfa genes, significantly increased expression was registred after five and also after 10 minutes, while increased Kras gene expression was detected 10 minutes after inducing wound and application of BPC 157. Discussion and conclusions This study confirmed most of the data obtained by previous studies. Activation of Akt1, Nos3, Pik3cd, Ptk2, Pxn, Src and Vegfa gene expression supports the idea that BPC 157 activates the PI3K-AKT-eNOS-VEGF and SRC-CAV-1-eNOS signaling pathways crucial for cell proliferation, migration and adhesion, and angiogenesis as suggested in studies by HSIEH et al. in 2017. and 2020., respectively. In the first study they discovered that, due the BPC 157, expression of VEGFA mRNA and protein was not changed, but VEGFR2 mRNA and protein indicated an increased expression after six hours with a peak of expression after 12 hours for mRNA and 9 hours for proteins, respectively (time periods studied were 3, 6, 12 and 24 hours after treatment). The same study showed, using a immunofluorescence, that BPC 157, just like VEGF, promotes the internalization of VEGFR2 on HUVEC cells. Since the internalization of VEGFR2 is followed by activation of Akt and eNOS, ie initiation of VEGFR2-AKT-eNOS signaling pathway, the expression of VEGFR2, Akt and eNOS proteins and their phosphorylated (activated) forms was analyzed in 10, 15 and 30 minutes after treatment. Results showed that BPC 157 causes phosphorylation of VEGFR2 rapidly, after 10 minutes, as Akt phosphorylation, while eNOS phosphorylation was noted after 15 minutes. That data suggest that BPC 157 has an extremely fast effect, as detected in our study with upregulated Akt1 and Nos3 mRNA expression two minutes and Vegfa five minutes after injury. In 2020. study HSIEH et al. discovered BPC 157 effect on vasorelaxation induction by activating eNOS/NO signalling. It also stimulated vascular endothelial cell migration and activated SRC-CAV1-eNOS signaling pathway. Expression of SRC, CAV1, eNOS proteins and their phosphorylated forms was analyzed in HUVEC cells using the Western blot 30 and 60 minutes after treatment. BPC 157 promoted phosphorylation of SRC and eNOS proteins while the amount of total SRC ans eNOS proteins remained unchanged. A similar thing happened with the pCAV1 protein, but the amount of total CAV1 protein was reduced. BPC 157 promotes NO formation (important role in regulation of inflammation), eNOS phosphorylation and it reduces CAV1-eNOS binding (increased eNOS activity is associated with decreased CAV1 binding). Data obtained for SRC protein correlates with previous 2010. in vitro study from CHANG et al. which demonstrated effect of BPC 157 on the increased migration rate of tendon fibroblast cells in a dose-dependent manner. It was confirmed with Western blot method which showed that the application of BPC 157 had no effect on the increased amount of Fak/Ptk2 protein and paxilin, but enhanced their phosphorylation. This effect can be associated with the activation of the PTK2(FAK)-SRCPXN signaling pathway which plays an important role in modulating cell adhesion and migration. Src protein cooperates with many tyrosine kinase receptors and can activate numerous signaling pathways, as SRC-CAV1-eNOS, PI3K/AKT and PTK2(FAK)-PXN. In this study, expression of Ptk2, Src and Pxn genes was analyzed, and the obtained data showed that BPC 157 application increased Ptk2 and Src gene expression after only two minutes, while the same effect on Pxn was noted after five minutes. An extensive study by KANG et al. in 2018. on an in vivo model of tumor cachexia also analyzed molecular mechanisms of BPC 157. RT-PCR analysis was done and expression of Mfn-2, PGC-1α and Pax mRNA was investigated. Decreased expression of all these genes was observed in cachexia animals while in BPC 157-treated cachexia animals the expression level was preserved. BPC 157 corrected both inflammatory and metabolic changes caused by the tumor. The phosphorylated forms of Foxo, Akt, mTOR i GSK-3β (transcription factor and regulatory proteins important for muscle proliferation and myogenesis) were analyzed using the Western blot and their phosphorylation was reduced in cachexia animals as opposed to those treated with BPC 157. Some studies investigated BPC 157 effect on PI3K-AKT signalling and eNOS. In 2018. and 2020. VUKOJEVIĆ et al. have shown that BPC 157 has activating effect to Nos3 expression, while study from CESAREC et al. in 2013. has shown that it reduces Nos3 expression. The reason for these contradictory data can be found in studies describing the effect of BPC 157 on the NO system where it interferes with the effects of agonists (Larginine, substrate molecules for NO) and antagonists of the NO system (L-NAME, NOS inhibitors). It indicates that BPC 157 regulates the amount of NO depending on the situation in the system. In addition, sampling and analysis were performed at different time periods: one and 24 hours from wound induction (increased expression of Nos3), at the beginning of inflammatory phase, and after four days (reduced Nos3 expression), when the inflammatory phase should enter a downward trajectory. In vivo studies from VUKOJEVIĆ et al. in 2018. and 2020. also examined the effect of BPC 157 on the mRNA expression of genes important for cell migration, proliferation and survival, and for the formation of reactive oxygen species, events important for overcoming induced injury. Activation of VEGFR2 signaling is very important for that events. It stimulates phospholipase C gamma (Plcg1) which is responsible for the activation of protein kinase C (Prkcg), whose downstream signaling targets are members of the MAPK signaling pathway (Raf, Ras, Mek, Erk2-1/Mapk1-3). Inferior caval vein ligature samples were analysed one and 24 hours after injury. Results indicated that BPC 157 increases the expression of the Egr (one hour) and Nos3, Srf, Kras (one hour and 24 hours) genes and decreases the expression of the Egr (24 hours), Vegfr2 (one hour and 24 hours) and Plcγ (24 hours) genes while the expression the Akt1 gene remained unchanged. Study done on ischemic/reperfusion injury in rat brain addressing the effect of BPC 157 discovered its effect on upregulated expression of Egr1, Akt1, Kras, Src, Foxo, Srf, Vegfr2, Nos3 and Nos1 genes, and downregulated expression of Nos2 and Nfkb genes, while no effect on Mapk1 gene expression was observed. Data collected in this study mostly correlates with those, as we showed that BPC 157 has an activating effect on Prkcg expression after only two minutes, while increased Plcg1 expression was observed after five minutes. Activation of the MAPK signaling pathway is manifested as increased expression of Braf, Mapk1 i Mapk3 observed in the fifth minute, and for Kras the same effect is seen after 10 minutes. BPC 157 also upregulated expression of Mapk14 five minutes after application. It is also very important in the healing process, especially in the inflammatory phase, as MAPK p38 (Mapk14) signaling pathway controls cytokine release. In addition to VEGFR2, activation of EGFR signaling also includes components of the MAPK signaling pathway and PI3K-AKT signaling pathway, respectively. Egfr expression analysis showed upregulating effect of BPC 157 noted after five minutes. Binding of the ligand to Egfr enables activation of Grb2 protein and triggering a MAPK signaling cascade. Also, it can activate PI3K-AKT, PLCγ-PKC and other signaling pathways. For this reason, the Grb2 gene was studied and its increased expression was proven due to the action of BPC 157. Cellular cytoskeletal proteins play a significant role during angiogenesis as they are responsible for cell shape, adhesion and motility. One of the main regulators of cytoskeleton protein expression is Srf – a transcription factor that regulates a number of genes involved in cell growth, migration, and cytoskeletal organization. Srf is important for the activation of some genes involved in endothelial proliferation, such as Fos and Egr1, so in the case of Srf deficiency, VEGF-induced signaling will not be able to activate the expression of Fos and Egr1. Analysis of the BPC 157 effect on Srf expression in this study showed an increased expression after five minutes. The same effects on Srf gene expression were demonstrated in previous studies from VUKOJEVIĆ et al. in 2018. and 2020. Activation of protein kinase C signaling pathways includes induction of transcription factors, Nfat and Egr1, respectively, and activation of the angiogenic response. Egr1 induces cytokines and the production of growth factors as well as the early formation of collagen, or extracellular matrix, and, like Srf, is a very important component of the healing process and angiogenesis. An in vitro study from TKALČEVIĆ et al. in 2007. done on Caco-2 cells showed that BPC 157 enhances EGR1 expression. The analysis was performed by RT-PCR method (effect was detected after 15 minutes) and Western blot (effect was detected after one hour). That data correlate with the results obtained in this study where increased expression of the Egr1 gene was demonstrated after only 5 minutes. Studies from 2018. and 2020. performed by VUKOJEVIĆ et al. analysing the effect of BPC 157 on Egr1 expression also support this data. Vegfa can cause rapid phosphorylation Hdac7 as early as five minutes, as described by WANG et al. in 2008. Plcg and Prkc activate Prkd followed by Hdac7 phosphorylation resulting in endothelial cell proliferation and migration. In this study, therefore, the effect of BPC 157 on Hdac7 gene expression was investigated and the result indicated increased expression after five minutes. The complexity of events in signaling pathways and the large number of interactions makes it difficult to clearly detect the action mechanism of BPC 157. However, is is indisputably proven to have a pleiotropic effect, not only on expression of different genes but also on their protein products triggering complex signaling cascades. Taking into account the results of this and previous studies, it can be concluded that BPC 157 acts extremely quickly (gene expression effects seen in two, five and ten minutes, respectively). It can have prolonged impact with modular or regulatory effects on different events involved in angiogenesis or inflammatory response (regulation of NO system, effect on expression and activation of certain genes and/or their protein products). In conclusion, BPC 157 has a proangiogenic effect proven in an in vivo skin wound model. Studied genes with protein products involved in angiogenic signaling pathways have different roles and mechanisms they affect as regulation of cellular processes is extremely complex and often intertwined. That is a puzzle that needs to be solved to elucidate molecular mechanism of BPC 157 action which can potentially lead to widespread use in a variety of pathological conditions