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GPR68 (OGR1) belongs to the proton-sensing G protein-coupled receptors that are involved
in cellular adaptations to pH changes during tumour development. Although expression of GPR68
has been described in many tumour cell lines, little is known about its presence in human tumour
entities. We characterised the novel rabbit monoclonal anti-human GPR68 antibody 16H23L16
using various cell lines and tissue specimens. The antibody was then applied to a large series of
formalin-fixed, paraffin-embedded normal and neoplastic human tissue samples. Antibody specificity
was demonstrated in a Western blot analysis of GPR68-expressing cells using specific siRNAs.
Immunocytochemical experiments revealed pH-dependent changes in subcellular localisation of the
receptor and internalisation after stimulation with lorazepam. In normal tissue, GPR68 was present in
glucagon-producing islet cells, neuroendocrine cells of the intestinal tract, gastric glands, granulocytes,
macrophages, muscle layers of arteries and arterioles, and capillaries. GPR68 was also expressed
in neuroendocrine tumours, where it may be a positive prognostic factor, in pheochromocytomas,
cervical adenocarcinomas, and endometrial cancer, as well as in paragangliomas, medullary thyroid
carcinomas, gastrointestinal stromal tumours, and pancreatic adenocarcinomas. Often, tumour
capillaries were also strongly GPR68-positive. The novel antibody 16H23L16 will be a valuable tool for
basic research and for identifying GPR68-expressing tumours during histopathological examinations.
In addition to the classical oestrogen receptors, ERα and ERβ, a G protein-coupled oestrogen receptor (GPER) has been identified that primarily mediates the rapid, non-genomic signalling of oestrogens. Data on GPER expression at the protein level are contradictory; therefore, the present study was conducted to re-evaluate GPER expression by immunohistochemistry to obtain broad GPER expression profiles in human non-neoplastic and neoplastic tissues, especially those not investigated in this respect so far. We developed and thoroughly characterised a novel rabbit monoclonal anti-human GPER antibody, 20H15L21, using Western blot analyses and immunocytochemistry. The antibody was then applied to a large series of formalin-fixed, paraffin-embedded human tissue samples. In normal tissue, GPER was identified in distinct cell populations of the cortex and the anterior pituitary; islets and pancreatic ducts; fundic glands of the stomach; the epithelium of the duodenum and gallbladder; hepatocytes; proximal tubules of the kidney; the adrenal medulla; and syncytiotrophoblasts and decidua cells of the placenta. GPER was also expressed in hepatocellular, pancreatic, renal, and endometrial cancers, pancreatic neuroendocrine tumours, and pheochromocytomas. The novel antibody 20H15L21 will serve as a valuable tool for basic research and the identification of GPER-expressing tumours during histopathological examinations.
Whether mice are an appropriate model for S. aureus infection and vaccination studies is a matter of debate, because they are not considered as natural hosts of S. aureus. We previously identified a mouse-adapted S. aureus strain, which caused infections in laboratory mice. This raised the question whether laboratory mice are commonly colonized with S. aureus and whether this might impact on infection experiments. Publicly available health reports from commercial vendors revealed that S. aureus colonization is rather frequent, with rates as high as 21% among specific-pathogen-free mice. In animal facilities, S. aureus was readily transmitted from parents to offspring, which became persistently colonized. Among 99 murine S. aureus isolates from Charles River Laboratories half belonged to the lineage CC88 (54.5%), followed by CC15, CC5, CC188, and CC8. A comparison of human and murine S. aureus isolates revealed features of host adaptation. In detail, murine strains lacked hlb-converting phages and superantigen-encoding mobile genetic elements, and were frequently ampicillin-sensitive. Moreover, murine CC88 isolates coagulated mouse plasma faster than human CC88 isolates. Importantly, S. aureus colonization clearly primed the murine immune system, inducing a systemic IgG response specific for numerous S. aureus proteins, including several vaccine candidates. Phospholipase C emerged as a promising test antigen for monitoring S. aureus colonization in laboratory mice. In conclusion, laboratory mice are natural hosts of S. aureus and therefore, could provide better infection models than previously assumed. Pre-exposure to the bacteria is a possible confounder in S. aureus infection and vaccination studies and should be monitored.