For GAPDH normalized ratio of mPGES-1: PGDH gene expression in normal (n = 6), sub-acute (n = 8) and chronic injured flexor tendons (n = 6). (B) Median values for 18S normalized ratio of mPGES-1: PGDH gene expression in normal (n = 6), sub-acute (n = 6) and chronic injured flexor tendons (n = 5), showing elevated mPGES-1:PGDH expression in sub-acute injury compared to normal and chronic injured tendons. doi:10.1371/journal.pone.0048978.gProstaglandins and Lipoxins in TendinopathyFigure 5. Representative Western blots illustrating expression of PGDH and b-actin in normal, sub-acute and chronic SDFT extracts. Monomeric (30 kDa) and dimeric (60 kDa) bands are shown for PGDH and a 42 kDa band for b-actin. Samples were loaded on a volume basis and the ratio of PGDH normalised to b-actin was calculated for each sample using band densitometric analysis. Graph shows densitometric analysis of western blots for PGDH in protein extracts prepared from normal (n = 7) sub-acute (n = 5) and chronic injured SDFTs (n = 8). The densitometric values were normalized to levels of b-actin expressed in each sample. There was a significant increase in PGDH in sub-acutely injured tendon extracts compared to normals but this was not significantly different in the chronic injury group. * P,0.05, **P,0.01. Mean values are shown, error bars denote standard deviation. doi:10.1371/journal.pone.0048978.gFigure 6. FPR2/ALX protein expression in natural tendon injury. The relationship between FPR2/ALX levels with age is shown in injured flexor tendons (n = 10). Horse age ranged between 4 and 1527786 16 years (mean 1164 years). FPR2/ALX expression was significantly reduced with increasing age (P = 0.0008, r2 = 0.77). Overlapping points are present for tendons derived from more than one 15 and 16 year old horses. doi:10.1371/journal.pone.0048978.gcapacity in the tissue. Furthermore, activated macrophages from aged humans and mice are reported to produce more PGE2 than macrophages from younger individuals [45] which may contribute to the greater frequency of tendon injury in older individuals through sustained activation of proteolytic action on the ECM. Whilst there are no equine specific antibodies available to order Ergocalciferol neutrophils or mast cells, precluding immunofluorescent analysis, we were not able to identify these cells by histology of injured tendons between 3? weeks post injury (data not shown). As we 15857111 were unable to get ��-Sitosterol ��-D-glucoside access tendons with injuries of less than 2 weeks duration, we cannot exclude the presence of these cells and their contribution to the synthesis of PGE2 at this earlier phase of injury. However as macrophages are known to release PGE2 and tendon injury has been shown to be associated with activation and recruitment of these cells [16], they represent an important source of PGE2 during tendon injury. Regulation of prostaglandin metabolism is not well documented for normal and pathologic tendons, although the majority of circulating prostaglandins are degraded in the pulmonary vasculature via PGDH [32]. However, tissue levels of PGE2 are finetuned by locally produced PGDH [46] and the net balance between synthesis and degradation may be a mechanism for controlling the action of PGE2. In the present study, the ratio of mPGES-1: PGDH was increased in sub-acute compared to chronic disease or normal tendons, suggesting potential aberration of these genes with disease phase. We propose that the altered intracellular prostaglandin regulation is attributable to a proportionat.For GAPDH normalized ratio of mPGES-1: PGDH gene expression in normal (n = 6), sub-acute (n = 8) and chronic injured flexor tendons (n = 6). (B) Median values for 18S normalized ratio of mPGES-1: PGDH gene expression in normal (n = 6), sub-acute (n = 6) and chronic injured flexor tendons (n = 5), showing elevated mPGES-1:PGDH expression in sub-acute injury compared to normal and chronic injured tendons. doi:10.1371/journal.pone.0048978.gProstaglandins and Lipoxins in TendinopathyFigure 5. Representative Western blots illustrating expression of PGDH and b-actin in normal, sub-acute and chronic SDFT extracts. Monomeric (30 kDa) and dimeric (60 kDa) bands are shown for PGDH and a 42 kDa band for b-actin. Samples were loaded on a volume basis and the ratio of PGDH normalised to b-actin was calculated for each sample using band densitometric analysis. Graph shows densitometric analysis of western blots for PGDH in protein extracts prepared from normal (n = 7) sub-acute (n = 5) and chronic injured SDFTs (n = 8). The densitometric values were normalized to levels of b-actin expressed in each sample. There was a significant increase in PGDH in sub-acutely injured tendon extracts compared to normals but this was not significantly different in the chronic injury group. * P,0.05, **P,0.01. Mean values are shown, error bars denote standard deviation. doi:10.1371/journal.pone.0048978.gFigure 6. FPR2/ALX protein expression in natural tendon injury. The relationship between FPR2/ALX levels with age is shown in injured flexor tendons (n = 10). Horse age ranged between 4 and 1527786 16 years (mean 1164 years). FPR2/ALX expression was significantly reduced with increasing age (P = 0.0008, r2 = 0.77). Overlapping points are present for tendons derived from more than one 15 and 16 year old horses. doi:10.1371/journal.pone.0048978.gcapacity in the tissue. Furthermore, activated macrophages from aged humans and mice are reported to produce more PGE2 than macrophages from younger individuals [45] which may contribute to the greater frequency of tendon injury in older individuals through sustained activation of proteolytic action on the ECM. Whilst there are no equine specific antibodies available to neutrophils or mast cells, precluding immunofluorescent analysis, we were not able to identify these cells by histology of injured tendons between 3? weeks post injury (data not shown). As we 15857111 were unable to access tendons with injuries of less than 2 weeks duration, we cannot exclude the presence of these cells and their contribution to the synthesis of PGE2 at this earlier phase of injury. However as macrophages are known to release PGE2 and tendon injury has been shown to be associated with activation and recruitment of these cells [16], they represent an important source of PGE2 during tendon injury. Regulation of prostaglandin metabolism is not well documented for normal and pathologic tendons, although the majority of circulating prostaglandins are degraded in the pulmonary vasculature via PGDH [32]. However, tissue levels of PGE2 are finetuned by locally produced PGDH [46] and the net balance between synthesis and degradation may be a mechanism for controlling the action of PGE2. In the present study, the ratio of mPGES-1: PGDH was increased in sub-acute compared to chronic disease or normal tendons, suggesting potential aberration of these genes with disease phase. We propose that the altered intracellular prostaglandin regulation is attributable to a proportionat.