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The Nodular lymphocyte-predominant Hodgkin lymphoma (NLPHL) as well as the T-cell/histiocyte-rich large B-cell lymphoma (THRLBCL) are rare types of malignant lymphomas. Both NLPHL and THRLBCL are frequently observed in middle-aged men with THRLBCL presenting frequently with an advanced Ann-Arbor stage with B-symptoms and associated with more aggressive courses.3 However, due to the limited number of tumor cells in the tissue of both NLPHL and THRLBCL, limited numbers of studies have been conducted on these lymphomas and current results are mainly based on general molecular genetic studies.
In order to obtain a better understanding for these disease forms as well as possible changes in their nuclear and cytoplasmatic sizes, the following study relied on the comparison of the different NLPHL forms and THRLBCL in terms of nuclear size and nuclear volume. This was carried out using both 2D and 3D analysis. During the 2D analysis of nuclear size and nuclear volume no significant differences could be presented between those groups. However, the 3D analysis of NLPHL and THRLBCL pointed out a slightly enlarged nuclear volume in THRLBCL. Furthermore, the analysis indicated a significantly increased cytoplasmatic size of THRLBCL compared to NLPHL forms. Nevertheless, differences occurred not only between the tumor cells of both disease forms, but also the T cells presented a larger nuclear volume in THRLBCL. B cells, which were considered as the control group, did not demonstrate any significant differences between the different groups. The presented results suggest an increased activity of T cells in THRLBCL, which is most likely to be interpreted as a response against the surrounding tumor cells and probably limits the proliferation of the tumor cells. Based on these results, the importance of 3D analysis is also evident due to the fact that it is clearly superior to 2D analysis. For a better understanding of both disease forms, it is therefore recommended to use the 3D technique in combination with molecular genetic analysis in future research.
Aortic valve (AV) and root replacement with composite graft and re-implantation of coronary arteries described first by Bentall and de Bono in 1968, is considered as a standard operation for treatment of different pathologies of the AV and aortic root. In centres where aortic valve and root repair techniques and Ross operation are well established, generally severely diseased patients remain indicated for this procedure. The aim of this study was to evaluate the early and long-term outcomes after Bentall-De Bono (BD) procedures in high-risk population with complex pathologies and multiple comorbidities.
Between 2005 and 2018, a total of 273 consecutive patients (median age 66 years; 23 % female) underwent AV and root replacement with composite-graft in so called button technique. We divided our population in the following groups: 1. acute type A aortic dissection group (ATAAD) (n = 48), 2. endocarditis group (n = 99) and 3. all other pathologies group (n = 126). The surgery has been per- formed emergent/urgent in 131 patients (49 %) and in 109 cases (40%) as a reoperation. Concomitant surgery was required in 97 patients (58%) and 167 pa- tients (61%) received a biological composite-graft.
Follow-up was completed in 96% (10 patients lost to follow-up) with a mean of 8.6 years (range 0.1-15.7 years), counting a total of 1450 patient-years. Thirty- day mortality was 17% (46 patients). The overall estimated survival in 5 and 10 years was 64% ± 3%) and 46% ±4 %). Group comparison showed a significant difference in favour of patient from the dissection group (p = 0.008). Implantation of a biological valve graft was associated with lower survival probability (p < 0.001). There was no significant difference in the freedom of reoperation rate between the groups. The same applies for freedom of postoperative endocarditis, thromboembolic events, and aortic prosthesis dysfunction. According to the uni- variate and multivariate logistic regression analysis primarily postoperative neu- rological dysfunction (OR 5.45), hypertension (OR 4.8) peripheral artery disease (OR 4.4), re-exploration for bleeding (OR 3.37) and postoperative renal replace- ment therapy (OR 3.09) were identified as leading predictors of mortality.
In conclusion, the BD operation can be performed with acceptable short- and long-term results in high-risk patients with complex aortic pathologies in a centre with well-established AV repair and Ross operation program.
Molecular oxygen (O2) is essential for numerous metabolic processes. Not surprisingly, hypoxia and the resulting adaptations play a pivotal role in pathophysiology, e.g., in cancer or in inflammatory diseases. Of note, myeloid cells are known to accumulate in hypoxic regions such as tumor cores or rheumatoid arthritis joints and may contribute to disease progression. While most studies so far concentrated on transcriptional adaptation by the hypoxia-inducible factors (HIF) 1 and 2 under short term hypoxia, prolonged oxygen deprivation and alternative post-transcriptional regulation are rather poorly investigated.
Consequently, the aim of the study was to generate a comprehensive overview of mRNA de novo synthesis and degradation and its contribution to total mRNA changes in monocytic cells in the course of hypoxia.
To this end, I used thiol-linked alkylation for the metabolic sequencing of RNA (SLAM-Seq) to characterize RNA dynamics under hypoxia. Specifically, I labeled monocytic THP-1 cells under normoxia (N), acute hypoxia (AH; 8 h 1% O2), or chronic hypoxia (CH; 72 h 1% O2) with 4-thiouridine (4sU), which allows for transcriptome-wide identification of de novo synthesized mRNAs and estimation of their half-lives. Total mRNA expression analyses revealed that most changes occurred under CH. Considering that HIF accumulation and resulting transcriptional regulation was shown to decline again under CH, I further analyzed the impact of RNA stability on gene expression. I observed a global reduction in RNA half-lives under hypoxia, indicative for the attenuation of energy-consuming protein synthesis upon oxygen deprivation. Moreover, I observed a subgroup of hypoxic destabilized transcripts with resulting decreased mRNA expression under CH, which consisted of 59 nuclear-encoded mitochondrial mRNAs. This might prevent futile production of new mitochondria under conditions, where mitochondria are even actively degraded to prevent production of detrimental reactive oxygen species.
While stability-regulated transcripts were mainly destabilized under hypoxia, the vast majority of differentially de novo synthesized transcripts were upregulated.
Functional analyses revealed not only hypoxia, but also cholesterol homeostasis and inflammatory response as top enriched terms, corroborating findings on total mRNA level. Focusing on hypoxia-altered cholesterol metabolism, I observed an 9 accumulation of early and a decrease in late cholesterol precursors, which are separated by several oxygen-dependent enzymatic steps. Although total cholesterol levels were only slightly reduced, my data indicate locally lowered endoplasmic reticulum (ER) cholesterol levels under hypoxia, which cause feedback activation of the ER cholesterol-sensing transcription factor sterol regulatory element-binding protein 2 (SREBP2) and induction of cholesterol biosynthesis enzymes. Interestingly, a broad range of interferon-stimulated genes (ISGs), mainly known for their antiviral function, was also induced under hypoxia with similar kinetics as SREBP2 targets, suggesting an immunometabolic crosstalk. While the availability of certain cholesterol biosynthesis intermediates as well as a direct involvement of SREBP2 seemed rather unlikely to cause hypoxic ISG induction, changes in intracellular cholesterol distribution appeared crucial for the hypoxic induction of chemokine-ISGs. Mechanistically, I found that MyD88-dependent toll-like receptor 4 (TLR4) signaling contributes to enhanced hypoxic ISG induction, likely sensitized by changes in cholesterol dynamics. Importantly, hypoxia amplified induction of chemokine-ISGs in monocytes upon treatment with severe acute respiratory syndrome coronavirus type 2 (SARS-CoV-2) spike protein via TLR4 similarly as after addition of infectious virus, which might contribute to systemic inflammation in hypoxemic patients with severe coronavirus disease-2019 (COVID-19).
Taken together, I comprehensively analyzed RNA dynamics in hypoxic monocytes. Specifically, I identified RNA stability as a modulating mechanism to limit production of mitochondria under oxygen-restricted conditions. Moreover, I characterized the immunometabolic crosstalk between disturbed cholesterol homeostasis and spontaneous induction of interferon (IFN)-signaling in hypoxic monocytes, which might contribute to systemic inflammation in severe cases of COVID-19.
The impact of the Covid-19 pandemic called for rapid responses in face of unprecedented challenges. In this context, earning more about the causative agent SARS-CoV-2 becomes imperative. Therefore, clinical virus isolates were studied with focus on infectivity, replication kinetic, and caspase activity.
Firstly, clinical specimens collected from patients were tested for infectivity in cell culture. Combined with polymerase chain reaction results, a formula predicting infectivity in cell culture based on abundance of viral RNA was developed. Additionally, analysis of different specimen types, sources, and material, elucidate the question of infectivity. Here, infectivity was demonstrated in specimens derived from different parts of the respiratory tract, including specimens collected from deceased persons. A protocol for virus isolation on human airway epithelium in air-liquid interface culture was established.
Secondly, replication kinetics of 20 clinical isolates were compared, including a subset of seven sequenced isolates. All isolates replicated in the colon epithelial cell culture model. Within the subset, differences between isolates carrying the D614G amino acid exchange and with original spike protein were observed.
Lastly, elevated caspase activity was demonstrated in two cell culture models including human airway epithelium in air-liquid interface culture.
Subsequently, caspase inhibition by small-molecule compound Emricasan and its effects on the cytopathic effect observed in cell culture were studied. Here, increased cell survival in a colon epithelial cell line was shown with unimpaired virus replication. Elevated caspase activity was identified as early marker of infection and validated by testing across 20 clinical virus isolates.
This study offers information on infectivity that can help shape the understanding of transmission risk. As such, parts of the data collected here were used for validation of rapid antigen tests. The insights gained by studying caspase activity contributed in part to the development of a drug screening method by Bojkova et al.,41 thus aiding routine laboratory workflow. It was demonstrated that Emricasan exhibits no antiviral effect, while the finding of increased cell survival in cell culture could give rise to further research on prevention of tissue damage.
Background: Previous studies have demonstrated that CF (Cystic Fibrosis) prognosis is dependent of three major parameters: FEV1 (Forced Expiratory Pressure in one second), BMI (Body Mass Index) and need of intravenous antibiotic therapy. The CF centres of Frankfurt, Germany, and Moscow, Russia, care for cystic fibrosis patients. We decided to investigate and compare both centers from 1990 to 2015. No comparable study has been published so far.
Method: German patient data was collected from the national cystic fibrosis database “Muko.web”. Missing values were extracted from the Hospital Information System. Russian patient data were taken directly from the medical records in Moscow. In a descriptive statistical analysis with Bias and R Studio the values were compared.
Result: A total of 428 patients from Moscow (217 male, 211 female; 348 (81,3%) were P. aeruginosa positive) and 159 patients from Frankfurt (92 male, 67 female; 137 (86,2%) with P. aeruginosa positive) were compared with regard to P. aeruginosa positivity, BMI, FEV1 and need of intravenous antibiotic therapy. CF patients in Moscow stratified by age groups had lower BMI than CF patients in Frankfurt (age 16-18: p=0,003; age 19-22: p=0,004; age 23-29: p<0,001; age 30-35: p<0,001; age 36-66: p=0,024). In a matching pairs analysis including 100 patients from Frankfurt and 100 patients from Moscow for the year 2015 FEV1 was significantly lower in Moscow patients (p<0,001).
Conclusion: BMI, FEV1 and need of intravenous therapy have significant impact on survival and on quality of life of CF patients. A lower BMI and a lower FEV1 result in a worse survival and determine the prognosis. This study showed a significant difference in prognostic parameters between Frankfurt and Moscow in the crosssectional analysis for the year 2015. A further study should evaluate this difference to show whether this difference will be found over a longer period of time.
The ubiquitin-related SUMO system represents a versatile post-translational modification pathway controlling a variety of cellular signalling networks. In mammalian cells, lysine residues of target proteins can be covalently modified with three SUMO isoforms (SUMO1, SUMO2 and SUMO3) resulting in conjugation of either single SUMO moieties or formation of poly-SUMO chains. Importantly, SUMO modification is a reversible process, where the deconjugation of SUMO from its substrates is mediated by SUMO proteases. In humans, the best-characterized subfamily is the SENP family of SUMO-specific isopeptidases comprised of SENP1-3 and SENP5-7. For undisturbed cellular signalling events, a proper balance of SUMO conjugation and deconjugation is crucial. SENPs fulfil the important function of counteracting SUMOylation. A key question is how the relatively low number of SENPs specifically controls the SUMOylation status of hundreds of cellular proteins.
The aim of this thesis was to uncover the regulation and substrate specificity of distinct SUMO isopeptidases in order to better understand their role in cellular signalling pathways.
In the first part of this work, we investigated the influence of hypoxia on SUMO signalling, in particular on the activity of SENPs. Importantly, we found that the catalytic activity of distinct SENPs (especially SENP1 and SENP3) is strongly but reversibly diminished under low oxygen. As a consequence, the SUMO modification of a specific subset of proteins is changed under hypoxia. We specifically identified proteins being hyperSUMOylated after 24 hours of hypoxia by SUMO1 immunoprecipitation followed by mass spectrometry. We further validated the transcriptional co-repressor BHLHE40 as hypoxic SUMO target and confirmed SENP1 as responsible isopeptidase for deconjugation of SUMOylated BHLHE40. We provide evidence that SUMO conjugation to BHLHE40 enhances its repressive functions on the expression of the metabolic master regulator PGC-1α. Therefore we propose a model where inactivation of SENP1 under hypoxia results in SUMOylated BHLHE40, possibly contributing to metabolic reprogramming under hypoxia.
To get insight into substrate selectivity of SENP family members, in particular SENP3 and SENP6, we choose a proteomic profiling strategy. For the identification of specific SUMO substrates controlled by SENP3, we applied a large-scale IP-MS approach in SENP3 KO and WT cells. The most strongly induced SUMO targets in the absence of SENP3 were key regulators of ribosome maturation. We identified factors involved in the remodelling of both 90S and 60S pre-ribosomes. SENP3 has already been described as being critically involved in maturation of the pre-60S subunit and 28S rRNA processing. Previously described SENP3-regulated master targets in this process are the ribosome maturation factors PELP1 and Las1L. Importantly, both were also identified as the most significantly regulated SENP3 targets in our unbiased proteomic approach. Importantly, however, enhanced SUMOylation was also detected on 90S-associated regulators, such as BMS1. Altogether, these data strengthen the functional link between SENP3 and ribosome biogenesis and point to a role of SENP3 beyond 60S maturation.
In addition to SENP3, we explored the substrate specificity of SENP6, which mainly acts on polymeric SUMO2/3 chains. Applying a proteomic profiling strategy, we were able to identify SENP6-controlled SUMO networks functioning in DNA damage response as well as chromatin organization. We demonstrated that SENP6 reverses polySUMOylation of several subunits of the cohesin complex, thereby regulating the SUMOylation status and chromatin association of this complex. Furthermore, we found a tight interaction of SENP6 with the hPSO4/PRP19 complex, involved in DNA damage response by activation of the ATR-CHK1 signalling cascade. In cells depleted of SENP6, we observe deficient recruitment of the co-activator ATRIP to chromatin which results in diminished CHK1 activation. We therefore illustrate a general role of SENP6 in the control of chromatin-associated protein networks involved in genome integrity and chromatin organization.
G-protein-coupled receptors (GPCRs) comprise the largest transmembrane receptor family encoded in the human genome. GPCRs mediate the effect of a wide diversity of stimuli including light, odorants, ions, lipids, small peptides, and hormones. GPR182 is a GPCR for which no endogenous ligand has been identified yet. In the absence of an identified ligand, GPR182 remained poorly understood, and its biological functions had remained elusive. The presented work shows that GPR182 is highly and specifically expressed in microvascular endothelial cells. Phylogenetically, GPR182 is closely related to the atypical chemokine receptor 3 (ACKR3). Here, I show that GPR182 binds the chemokines CXCL10, -12 and -13. Similarly to other so-called atypical chemokine receptors, GPR182 is not coupled to G-proteins but is rather constitutively internalized following β-arrestin 2 recruitment. Consistent with potential scavenger functions, we detected increased concentration of the chemokines which bind the receptor in the plasma of Gpr182 deficient mice. Finally, we show that GPR182 plays an essential role in maintaining hematopoietic stem cells within the bone marrow niche. In summary, the data indicate that GPR182 is a novel member of the group of atypical chemokine receptors, which plays an important role in the chemokine/chemokine receptor network.
In haploidentical stem cell transplantation (SCT), achieving a balance between graft versus host disease (GvHD), graft versus leukemia effect (GvL) and bridging the vulnerable phase of aplasia against viral infections is still a challenge. Graft preparation strategies attempt to achieve this balance by removing and retaining harmful and helpful cells. At this point it is known that T cell subpopulations hold different properties concerning GvHD promotion and immunocompetence towards pathogens. CD45RA+ naïve T cells show the greatest, while CD45RO+ memory T cells show less alloreactive potential but provide immunocompetence. CD45RA depletion is a promising new approach to graft processing that potentially combines GvHD prevention, GvL promotion and transfer of immunological competence by removing potentially harmful CD45RA+ naïve T cells and retaining CD45RO+ memory cells. This work focused on manufacturing CD45RA-depleted grafts within a one- or two-step approach, as well as a feasibility assessment of the process and the establishment of a 10-color fluorescence activated cell sorting (FACS) measurement panel for clinical-scale graft generation. CD45RA depletions were conducted from granulocyte-colony stimulated factor (G-CSF) mobilized peripheral blood stem cells (PBSC) applying two different strategies, direct depletion of CD45RA+ cells (one-step approach), or depletion following preceding CD34 selection. A 10-color FACS measurement panel was established ensuring quality control and enabling preliminary data acquisition on CD45RA co-expression for cell loss estimations. Residual virus-specific T cells after depletion were measured using MHC multimers. It was observed that the depletion antibody occupied the cell binding sites, resulting in insufficient binding of the fluorescent dye for subsequent FACS measurement. Therefore, three FACS antibodies were tested and compared, and CD45RA-PE (clone:2H4) was found to be the best choice for reliable cell detection. To further characterize residual T cells, two homing markers, CD62L and CCR7, were compared, with particular attention paid to the expression of the surface markers after cooling. Both markers were complementary to each other, resulting in the decision to include an additional FACS measuring tube whenever samples are cooled or further T cell characterization is needed. With a median log depletion of -3.9 (one-step) and -3.8 (two-step) data showed equally efficient removal of CD45RA+CD3+ T cells for both approaches. Close to complete B cell removal was obtained without additional reagent use. However, also close to complete NK cell loss occurred due to high CD45RA co-expression. Stem cells recovered at a median of 52% (range: 49.7 - 67.2%) after one-step CD45RA depletion. CD45RO+ memory T cells recovery was statistically not differing between both approaches. Virus-specific T cells were detectable after depletion, suggesting that virus-specific immunocompetence is transferable. In conclusion, CD45RA depletions are equally feasible for both approaches when performed from fresh, non-cryopreserved starting products, show reliable reduction of CD45RA and B cells, but also result in co-depletion of NK cells. Stem cell recovery and NK cell losses must be considered carefully especially regarding overcoming HLA barriers, pathogen protection during aplasia, early engraftment an GvL. Therefore, a combination of CD45RA-depleted products with already established other processing methods to ensure sufficient stem and NK cells is desirable to allow high clinical flexibility.
While B-cell acute lymphoblastic leukaemia (B-ALL) can be described as the leukaemia of childhood, chronic myeloid leukaemia (CML) mostly develops in elderly individuals. Understanding and utilising mechanisms involved in the development and persistence of these leukaemias as possible targets for treatment strategies has received particular interest. Processes that happen in the vicinity of the cancerous cells themselves could influence cancer growth and behaviour and hence can serve as novel targets, leading to the development of two-pronged therapies that act both on leukaemic cells directly as well as their niche. The niche in the case of leukaemia is the bone marrow microenvironment (BMM) where these cells are not only generated but also instructed and protected. As the BMM is situated inside bones that undergo drastic changes and growth processes during the ageing process, the BMM itself is also being altered throughout life. These alterations and the very process of expansion itself may therefore also provide distinct regulatory influences on the cells (healthy or malignant) that are generated inside this niche, leading to the question: Does the age of the bone marrow microenvironment differentially influence the development of (“childhood”) B-ALL versus (“adult”) CML by the release of cytokines?
In previous studies by the host-laboratory the age distribution of B-ALL versus CML in a murine transduction/ transplantation model could be recapitulated; young mice which received the same number of leukaemia-initiating cells as their old counterparts died significantly earlier of B-ALL while showing a significantly delayed clinical course, when they were suffering from CML. The tumour load and other leukaemia-associated parameters also showed a clear disposition towards preferential induction of CML in elderly and B-ALL in younger mice.
In this project we could support the hypothesis that the age of the BMM differentially influences the proliferation of leukaemic cells and thereby the development and persistence of different types of leukaemias by utilising different in vitro culture experiments. Specifically, we could show that young (compared to old) bone marrow
11 stroma cells (BMSC) support the growth of (BCR-ABL1+) B-ALL cells both in a direct, cell on cell co-culture setting, as well as in young BMSC-derived conditioned medium. This supports the hypothesis that varying factors are differentially released from a young versus an old BMM and influence the growth of the leukaemia cells. The opposite might be true for CML cells (BCR-ABL1+ 32D cells); BMSC obtained from old animals showed a tendency to support their growth more profoundly than cells acquired from young animals.
Possible proteins responsible for the distinct regulation of myeloid versus lymphatic leukaemic cells by young versus old BMM have also been studied. We investigated C-X-C motif chemokine 13 (CXCL13) and growth differentiation factor 11 (GDF11) in their effect on leukaemia cells, as both proteins having previously been described to have tumour-modelling properties and age-dependent levels (see below).
We identified an increased secretion of CXCL13, a B-cell chemotactic factor, into conditioned medium from young versus old BMSC. In accordance with this we found migration of B-ALL cells towards BMSC from young compared to old mice to be improved, while adhesion of both B-ALL and CML cells to young versus old BMSC did not show any differences. By blocking CXCL13 the proliferation-supporting effect of young BMSC on B-ALL cells could be diminished. Similar effects could be demonstrated by blocking GDF11.
In the case of CML cells we could observe the opposite effect; blocking CXCL13 and GDF11 increased their proliferation in a co-culture with BMSC. This supported our hypothesis that both cytokines differentially regulate B-ALL and CML behaviour. After the completion of this thesis, another member of the host-laboratory convincingly demonstrated the role of BMM age in the regulation of B-ALL via CXCL13 signalling (see discussion).
Treatment response to neoadjuvant chemoradiotherapy (nCRT) varies considerably among individual patients in advanced rectal cancer indicating a clinical need for markers to predict treatment efficacy and to stratify patients for future personalized treatment. In recent years, there is a tremendous evidence on a pivotal impact of immune components on the development/pathogenesis of cancer and on mediating response to radiation and chemotherapy. Moreover, liquid biopsy biomarkers have become increasingly attractive to predict treatment response because they are easy to collect, reflect information on different aspects of tumor biology and can be accurately measured by standardized methods.
This study aimed to investigate the peripheral blood and tumor tissue immune cell contexture in patients with rectal adenocarcinoma treated with nCRT and chemotherapy (CT) within a prospective randomized phase II CAO-ARO-AIO-12 trial, conducted in the context of DKTK (Deutsches Konsortium für translationale Krebsforschung) and FCI (Frankfurt Cancer Institute), to address the questions whether peripheral blood and/or primary tumor immune contexture predict for treatment response, were modulated by nCRT/CT and correlated with each other. By this, immune cell components were assayed by flow cytometry from peripheral blood mononuclear cells (PBMCs) at baseline, day 43, and pre-surgery of 22 patients treated with nCRT/CT and subsequently correlated with pathologic treatment response. Immunophenotyping was performed applying different staining panels covering myeloid immune cells and human leukocyte antigen (HLA) molecules, T lymphocyte subpopulations and programmed cell death (PD)-1 protein expression and regulatory T cells (Tregs). In addition, tumor tissue samples from pre-therapeutic biopsies and surgical specimens were analyzed by immunohistochemistry and multiparametric immunofluorescence.
The present prospective study raised the following issues. First, peripheral lymphocytes seem to play a crucial role in the nCRT/CT mediated systemic anticancer immunological response. Second, among the various lymphocyte subsets, peripheral blood, but not tissue resident T lymphocytes seem to play a central role in predicting treatment response. By this, baseline blood phenotyping revealed a lymphocyte distribution with high numbers of (CD3+CD4+) T helper cells and low numbers of (CD3+CD8+) cytotoxic T cells expressing PD1, activation markers GranzymeB, perforin and HLA-DR to be associated with an improved response (ypT0ypN0) to nCRT/CT in the patient’s cohort investigated. Further, a decrease in B lymphocyte (CD3+CD19+) count correlated with intermediate and impaired response while an elevated monocyte (CD14+CD33+) levels predicted a complete and intermediate (ypT1-4ypN0) response to nCRT/CT. On a tissue level, patients with a complete response displayed a decrease in the amount of infiltrating neutrophils as the immunoscore of CD15+ cells was significantly higher in patients’ biopsies compared to post-nCRT/CT surgical specimen, while in both, patients with complete and intermediate response an increase of natural killer (CD56+) cell density and GranzymeB expression was observed. Finally, no significant correlation was observed between peripheral blood and tissue immune marker expression.
To validate and expand these findings, a continuation of the analysis in an extended patient cohort is necessary. In addition, a detailed insight on the role of peripheral blood T cells and monocytes and their activation status is desirable. Further, in a follow-up trial, soluble activation markers/cytokines should be assayed, further distinguishing activated from resting or exhausted lymphocytes.