Translational research using animal models has traditionally involved genetically modified rodents; however there is increasing use of other novel genetically engineered species. As histology laboratories interface with researchers studying these novel species there will be many situations in which protocols will need to be adapted to the species, model and research goals. This paper gives examples of protocol adaptations to meet research needs and addresses common considerations that should be addressed for all research tissues submitted to the histotechnology laboratory. Positioning the histotechnologist, as well as the investigator, to meet the challenges associated with novel research models will help maximize research efficacy and quality.
In a diagnostic setting, the histology laboratory is a key resource for production of quality tissues so the pathologist can make an appropriate diagnosis. In a research setting, the histology laboratory is a valuable resource in providing an excellent quality product for publications and grants for the investigator. Optimal collaboration with research investigators requires that histotechnologists recognize the diverse challenges and opportunities in research. This paper emphasizes the importance of positive interaction with researchers, optimizing professional service for these clients and recognizing key services of histology laboratories in a research setting to maximize success.
Arginases are a family of enzymes that convert L-arginine to L-ornithine and urea. Alterations in expression of the isoform arginase-I are increasingly recognized in lung diseases such as asthma and cystic fibrosis. To define expression of murine arginase-I in formalin-fixed tissues, including lung, an immunohistochemical protocol was validated in murine liver; a tissue that has distinct zonal arginase-I expression making it a useful control. In the lung, arginase-I immunostaining was observed in airway surface epithelium and this decreased from large to small airways; with a preferential staining of ciliated epithelium versus Clara cells and alveolar epithelia. In submucosal glands, the ducts and serous acini had moderate immunostaining, which was absent in mucous cells. Focal immunostaining was observed in alveolar macrophages, endothelial cells, pulmonary vein cardiomyocytes, pulmonary artery smooth muscle, airway smooth muscle and neurons of ganglia of the lung. Arginase-I immunostaining was also detected in other tissues including salivary glands, pancreas, liver, skin, and intestine. Differential immunostaining was observed between sexes in submandibular salivary glands; arginase-I was diffusely expressed in the convoluted granular duct cells of females, but was rarely noted in males. Strain specific differences were not detected. In one mouse with an incidental case of lymphoma, neoplastic lymphocytes lacked arginase-I immunostaining, in contrast to immunostaining detected in non-neoplastic lymphocytes of lymphoid tissues. The use of liver tissue to validate arginase-I immunohistochemistry produced consistent expression patterns in mice and this approach can be useful to enhance consistency of arginase-I immunohistochemical studies.
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