Small RNAs in Seminal Plasma as Novel Biomarkers for Germ Cell Tumors.

Circulating miRNAs secreted by testicular germ cell tumors (TGCT) show great potential as novel non-invasive biomarkers for diagnosis of TGCT. Seminal plasma (SP) represents a biofluid closer to the primary site. Here, we investigate whether small RNAs in SP can be used to diagnose men with TGCTs or the precursor lesions, germ cell neoplasia in situ (GCNIS). Small RNAs isolated from SP from men with TGCTs (n = 18), GCNIS-only (n = 5), and controls (n = 25) were sequenced. SP from men with TGCT/GCNIS (n = 37) and controls (n = 22) were used for validation by RT-qPCR. In general, piRNAs were found at lower levels in SP from men with TGCTs. Ten small RNAs were found at significantly (q-value < 0.05) different levels in SP from men with TGCT/GCNIS than controls. Random forests classification identified sets of small RNAs that could detect either TGCT/GCNIS or GCNIS-only with an area under the curve of 0.98 and 1 in ROC analyses, respectively. RT-qPCR validated hsa-miR-6782-5p to be present at 2.3-fold lower levels (p = 0.02) in the SP from men with TGCTs compared with controls. Small RNAs in SP show potential as novel biomarkers for diagnosing men with TGCT/GCNIS but validation in larger cohorts is needed.

Transcriptome profiling of mice testes following low dose irradiation.

BACKGROUND: Radiotherapy is used routinely to treat testicular cancer. Testicular cells vary in radio-sensitivity and the aim of this study was to investigate cellular and molecular changes caused by low dose irradiation of mice testis and to identify transcripts from different cell types in the adult testis. METHODS: Transcriptome profiling was performed on total RNA from testes sampled at various time points (n = 17) after 1 Gy of irradiation. Transcripts displaying large overall expression changes during the time series, but small expression changes between neighbouring time points were selected for further analysis. These transcripts were separated into clusters and their cellular origin was determined. Immunohistochemistry and in silico quantification was further used to study cellular changes post-irradiation (pi). RESULTS: We identified a subset of transcripts (n = 988) where changes in expression pi can be explained by changes in cellularity. We separated the transcripts into five unique clusters that we associated with spermatogonia, spermatocytes, early spermatids, late spermatids and somatic cells, respectively. Transcripts in the somatic cell cluster showed large changes in expression pi, mainly caused by changes in cellularity. Further investigations revealed that the low dose irradiation seemed to cause Leydig cell hyperplasia, which contributed to the detected expression changes in the somatic cell cluster. CONCLUSIONS: The five clusters represent gene expression in distinct cell types of the adult testis. We observed large expression changes in the somatic cell profile, which mainly could be attributed to changes in cellularity, but hyperplasia of Leydig cells may also play a role. We speculate that the possible hyperplasia may be caused by lower testosterone production and inadequate inhibin signalling due to missing germ cells.

Microdissection of gonadal tissues for gene expression analyses.

Laser microdissection permits isolation of specific cell types from tissue sections or cell cultures. This may be beneficial when investigating the role of specific cells in a complex tissue or organ. In tissues with easily distinguishable morphology, a simple hematoxylin staining is sufficient, but in most cases a more specific staining is required to identify which cells to microdissect. We have established two staining protocols for frozen sections (1) Oil red O, which stains lipid droplet in fat cells and steroid-producing cells and (2) NBT BCIP, which stains cells expressing an alkaline phosphatase enzyme, such as fetal germ cells, testicular carcinoma in situ cells, and putatively also other early stem cell populations. We have applied these protocols for microdissection of rat Leydig cells, fetal human and zebrafish germ cells, and human testicular germ cell tumors, but the staining protocols could also be used in other species and for other cell types containing lipid droplets or expressing alkaline phosphatase. Both protocols ensure a morphology that enables microdissection of single cells with RNA quality sufficient for subsequent gene expression analysis. However, RNA yields after microdissection and purification are small, and therefore, two rounds of linear amplification are recommended prior to gene expression analysis.