Open Access

Our understanding of human biology and disease is based on the last millennia’s gain of knowledge, which has been exponentially accelerated since the invention of optical and "biochemical" microscopes like transcriptomics and other omics technologies. In order to broaden our knowledge of an important human transcription factor, T-Cell Acute Lymphocytic Leukemia 1 (TAL1), some of these technologies were used. TAL1’s gene or promoter structure is altered in about 20-30% of T-ALL. In addition, there is an increase in TAL1 expression in ca. 60% of pediatric and about 45% of adult T-ALL. Physiologically, TAL1 is an indispensable factor in hematopoiesis: in the murine knockout model, blood cells vanish in the early embryonic period. In addition, the TF is also relevant in adult erythropoiesis. Accordingly, the identification of novel TAL1 target genes was significant both for clinical reasons and in order to understand the hematopoietic functions. We performend a combined RNA- and ChIPseq approach. After a lentiviral mediated knockdown in K562 cells RNAseq was performed using the Illumina high-throughput method. Overall, the RNAseq yielded one billion good quality sequencing fragments. They made identification of up- and downregulated transcripts as well as associated biological processes, cellular components, molecular function and dominant KEGG signaling pathways possible. Furthermore, more than 2-fold altered coding transcripts and lncRNA were analyzed for relevant TAL1-binding in the transcription start area. There were 3205 significantly altered coding transcripts and 5136 significantly altered lncRNA. By integrating an Encode TAL1-ChIPseq in K562 cells (using a cutoff fold change of 2x) a relevant TAL1 binding could be detected with 71 coding and 416 lncRNA genes. The combination of RNA- and ChIPseq yields a wealth of relevant results. Accordingly, TAL1 has complex pro- and anti-malignant effects in all areas of oncogenesis like described by Hanahan and Weinberg. Various interactions with target genes and signaling cascades in inter alia proliferation (e.g. HEMGN, MYC, AHI1, YPEL3, BTG2), angiogenesis (e.g. EGFL7, LTBP3), apoptosis (e.g. BCL3, BCL2A1, BMF), immune evasion (e.g. CMTM6) and inflammation (e.g. IL23 and PTGS1) have been revealed, thus complementing the knowledge about pro- and anti-oncogenic effects of TAL1. In addition, it was possible to identify target genes relevant for erythropoiesis and possible osteogenesis. Concerning lncRNA, interesting potential effectors have been identified. However, they still need to be functionally characterized. Relating the results to Virchow’s first description of leukemia as "white blood" the role of TAL1 in leukemia’s genesis but also in erythropoiesis has been confirmed and extended, thus contributing to explain Virchow’s observation: "...therefore, when I speak of white blood, I mean in fact a blood in which the proportion between the red and colorless (in white) blood corpuscles is reversed ...” (Virchow R. Weisses Blut. Frorieps Notizen 1845;36:151-156).

Mesenchymal stromal/stem cells (MSCs) are immature multipotent cells, which represent a rare population in the perivascular niche within nearly all tissues. The most abundant source to isolate MSCs is adipose tissue. Currently, perirenal adipose tissue is rarely described as the source of MSCs. MSCs were isolated from perirenal adipose tissue (prASCs) from patients undergoing tumor nephrectomies, cultured and characterized by flow cytometry and their differentiation potential into adipocytes, chondrocytes, osteoblasts and epithelial cells. Furthermore, prASCs were stimulated with lipopolysaccharide (LPS), lipoteichoic acid (LTA) or a mixture of cytokines (cytomix). In addition, prASC susceptibility to human cytomegalovirus (HCMV) was investigated. The expression of inflammatory readouts was estimated by qPCR and immunoassay. HCMV infection was analyzed by qPCR and immunostaining. Characterization of cultured prASCs shows the cells meet the criteria of MSCs and prASCs can undergo trilineage differentiation. Cultured prASCs can be induced to differentiate into epithelial cells, shown by cytokeratin 18 expression. Stimulation of prASCs with LPS or cytomix suggests the cells are capable of initiating an inflammation-like response upon stimulation with LPS or cytokines, whereas, LTA did not induce a significant effect on the readouts (ICAM-1, IL-6, TNFα, MCP-1 mRNA and IL-6 protein). HCMV broadly infects prASCs, showing a viral load dependent cytopathological effect (CPE). Our current study summarizes the isolation and culture of prASCs, clearly characterizes the cells, and demonstrates their immunomodulatory potential and high permissiveness for HCMV

Creatinine and proteinuria are used to monitor kidney transplant patients. However, renal biopsies are needed to diagnose renal graft rejection. Here, we assessed whether the quantification of different urinary cells would allow non-invasive detection of rejection. Urinary cell numbers of CD4+ and CD8+ T cells, monocytes/macrophages, tubular epithelial cells (TEC), and podocalyxin(PDX)-positive cells were determined using flow cytometry and were compared to biopsy results. Urine samples of 63 renal transplant patients were analyzed. Patients with transplant rejection had higher amounts of urinary T cells than controls; however, patients who showed worsening graft function without rejection had similar numbers of T cells. T cells correlated with histological findings (interstitial inflammation p = 0.0005, r = 0.70; tubulitis p = 0.006, r = 0.58). Combining the amount of urinary T cells and TEC, or T cells and PDX+ cells, yielded a significant segregation of patients with rejection from patients without rejection (all p < 0.01, area under the curve 0.89–0.91). Urinary cell populations analyzed by flow cytometry have the potential to introduce new monitoring methods for kidney transplant patients. The combination of urinary T cells, TEC, and PDX-positive cells may allow non-invasive detection of transplant rejection.

The kidneys play a vital role in the basic physiological functions of the body. Kidney dysfunction impairs these physiological functions and can lead to a wide range of diseases. Damage to the kidney cells can be caused by a variety of ischemic, toxic or immunological complaints that lead to inflammation and cell death, which can lead to organ damage and, ultimately, complete failure. Although the mechanisms underlying acute kidney injury (AKI) and chronic kidney disease (CKD) are quite distinct, clinical evidence suggests that the two conditions are inextricably interconnected [1]. AKI and CKD, regardless of the underlying cause, have inflammation and activation of the immune system as the common underlying mechanisms. Inflammation, a process aimed, in principle, at detecting and fighting harmful pathogens, is, therefore, a major pathogenic mechanism for both AKI and CKD [1]. While the kidney has the remarkable ability to regenerate after an acute injury and can recover completely, depending on the type of kidney lesion, the options for clinical interventions are currently limited to fluid management and extracorporeal kidney support. However, persistent chronic inflammation can trigger renal fibrosis and chronic kidney disease. The investigation of the molecular mechanisms involved in each individual injury is currently insufficiently understood.

Mesenchymal stromal/stem cells and their derivates are the most promising cell source for cell therapies in regenerative medicine. The application of extracellular vesicles (EVs) as cell-free therapeuticals requires particles with a maximum regenerative capability to enhance tissue and organ regeneration. The cargo of mRNA and microRNA (miR) in EVs after hypoxic preconditioning has not been extensively investigated. Therefore, the aim of our study was the characterization of mRNA and the miR loading of EVs. We further investigated the effects of the isolated EVs on renal tubular epithelial cells in vitro. We found 3131 transcripts to be significantly regulated upon hypoxia. Only 15 of these were downregulated, but 3116 were up-regulated. In addition, we found 190 small RNAs, 169 of these were miRs and 21 were piwi-interacting RNAs (piR). However, only 18 of the small RNAs were significantly altered, seven were miRs and 11 were piRs. Interestingly, all seven miRs were down-regulated after hypoxic pretreatment, whereas all 11 piRs were up-regulated. Gene ontology term enrichment and miR-target enrichment analysis of the mRNAs and miR were also performed in order to study the biological background. Finally, the therapeutic effect of EVs on human renal tubular epithelial cells was shown by the increased expression of three anti-inflammatory molecules after incubation with EVs from hypoxic pretreatment. In summary, our study demonstrates the altered mRNA and miR load in EVs after hypoxic preconditioning, and their anti-inflammatory effect on epithelial cells.