Jeremy Price

The origin and development of nonlymphoid tissue CD103+ DCs

CD103+ dendritic cells (DCs) in nonlymphoid tissues are specialized in the cross-presentation of cell-associated antigens. However, little is known about the mechanisms that regulate the development of these cells. We show that two populations of CD11c+MHCII+ cells separated on the basis of CD103 and CD11b expression coexist in most nonlymphoid tissues with the exception of the lamina propria. CD103+ DCs are related to lymphoid organ CD8+ DCs in that they are derived exclusively from pre-DCs under the control of fms-like tyrosine kinase 3 (Flt3) ligand, inhibitor of DNA protein 2 (Id2), and IFN regulatory protein 8 (IRF8). In contrast, lamina propria CD103+ DCs express CD11b and develop independently of Id2 and IRF8. The other population of CD11c+MHCII+ cells in tissues, which is CD103−CD11b+, is heterogenous and depends on both Flt3 and MCSF-R. Our results reveal that nonlymphoid tissue CD103+ DCs and lymphoid organ CD8+ DCs derive from the same precursor and follow a related differentiation program.

Deciphering the transcriptional network of the dendritic cell lineage

Although much progress has been made in the understanding of the ontogeny and function of dendritic cells (DCs), the transcriptional regulation of the lineage commitment and functional specialization of DCs in vivo remains poorly understood. We made a comprehensive comparative analysis of CD8+, CD103+, CD11b+ and plasmacytoid DC subsets, as well as macrophage DC precursors and common DC precursors, across the entire immune system. Here we characterized candidate transcriptional activators involved in the commitment of myeloid progenitor cells to the DC lineage and predicted regulators of DC functional diversity in tissues. We identified a molecular signature that distinguished tissue DCs from macrophages. We also identified a transcriptional program expressed specifically during the steady-state migration of tissue DCs to the draining lymph nodes that may control tolerance to self tissue antigens.

BRAF-V600E expression in precursor versus differentiated dendritic cells defines clinically distinct LCH risk groups

The Rockefeller University Press

CDKN1A regulates Langerhans cell survival and promotes Treg cell generation upon exposure to ionizing irradiation

30.00 J. Exp. Med. 2014 Vol. 211 No. 4 669-683 www.jem.org/cgi/doi/10.1084/jem.20130977 669 Langerhans cell histiocytosis (LCH) is characterized by inflammatory lesions that include pathological langerin+ DCs. LCH has pleotropic clinical presentations ranging from single lesions cured by curettage to potentially fatal multisystem disease. The first descriptions of LCH, including Hand-Schüller-Christian disease and Letter-Siwe disease, were based on anatomical location and extent of the lesions (Arceci, 1999). The diagnosis of high-risk LCH, defined by involvement of “risk organs” which include BM, liver, and spleen, conferred mortality rates >20%, where patients with disease limited to non-risk organs (low-risk LCH) had nearly 100% survival, CORRESPONDENCE Carl Allen: ceallen@txch.org OR Miriam Merad: miriam.merad@mssm.edu

Predictive factors and management of rectal bleeding side effects following prostate cancer brachytherapy.

Treatment with ionizing radiation (IR) can lead to the accumulation of tumor-infiltrating regulatory T cells (Treg cells) and subsequent resistance of tumors to radiotherapy. Here we focused on the contribution of the epidermal mononuclear phagocytes Langerhans cells (LCs) to this phenomenon because of their ability to resist depletion by high-dose IR. We found that LCs resisted apoptosis and rapidly repaired DNA damage after exposure to IR. In particular, we found that the cyclin-dependent kinase inhibitor CDKN1A (p21) was overexpressed in LCs and that Cdkn1a−/− LCs underwent apoptosis and accumulated DNA damage following IR treatment. Wild-type LCs upregulated major histocompatibility complex class II molecules, migrated to the draining lymph nodes and induced an increase in Treg cell numbers upon exposure to IR, but Cdkn1a−/− LCs did not. Our findings suggest a means for manipulating the resistance of LCs to IR to enhance the response of cutaneous tumors to radiotherapy.Treatment with ionizing irradiation (IR) may lead to accumulation of tumor-infiltrating T regulatory (Treg) cells and subsequent tumor resistance to radiotherapy. Here we focused on the contribution of the epidermal mononuclear phagocytes, Langerhans cells (LCs), to this phenomenon because of their ability to resist depletion by high-dose IR. We found that LCs resisted apoptosis and rapidly repaired DNA damage post-IR. Particularly, we found that CDKN1A (cyclin-dependent kinase inhibitor 1A, also known as p21) was overexpressed in LCs, and that Cdkn1a−/− LCs underwent apoptosis and accumulated DNA damage following IR treatment. Wild-type, but not Cdkn1a−/−, LCs up-regulated major histocompatibility complex class II molecules, migrated to the draining lymph nodes and increased Treg cell numbers upon exposure to IR. These findings suggest a means for manipulating LC IR-resistance to increase cutaneous tumor response to radiotherapy.

Langerhans cell homeostasis and turnover after nonmyeloablative and myeloablative allogeneic hematopoietic cell transplantation

PURPOSE To report on the incidence, nature, and management of rectal toxicities following individual or combination brachytherapy following treatment for prostate cancer over a 17-year period. We also report the patient and treatment factors predisposing to acute ≥ grade 2 proctitis. METHODS AND MATERIALS A total of 2752 patients were treated for prostate cancer between October 1990 and April 2007 with either low-dose-rate brachytherapy alone or in combination with androgen depletion therapy (ADT) or external beam radiation therapy (EBRT) and were followed for a median of 5.86 years (minimum 1.0 years; maximum 19.19 years). We investigated the 10-year incidence, nature, and treatment of acute and chronic rectal toxicities following BT. Using univariate, and multivariate analyses, we determined the treatment and comorbidity factors predisposing to rectal toxicities. We also outline the most common and effective management for these toxicities. RESULTS Actuarial risk of ≥ grade 2 rectal bleeding was 6.4%, though notably only 0.9% of all patients required medical intervention to manage this toxicity. The majority of rectal bleeding episodes (72%) occurred within the first 3 years following placement of BT seeds. Of the 27 patients requiring management for their rectal bleeding, 18 underwent formalin treatment and nine underwent cauterization. Post-hoc univariate statistical analysis revealed that coronary artery disease (CAD), biologically effective dose, rectal volume receiving 100% of the prescription dose (RV100), and treatment modality predict the likelihood of grade ≥2 rectal bleeding. Only CAD, treatment type, and RV100 fit a Cox regression multivariate model. CONCLUSIONS Low-dose-rate prostate brachytherapy is very well tolerated and rectal bleeding toxicities are either self-resolving or effectively managed by medical intervention. Treatment planning incorporating adjuvant ADT while minimizing RV100 has yielded the best toxicity-free survival following BT.

Reply to: "Subverting misconceptions about radiation therapy".

Background Langerhans cells (LCs) are self-renewing epidermal myeloid cells that can migrate and mature into dendritic cells. Recipient LCs that survive cytotoxic therapy given in preparation for allogeneic hematopoietic cell transplantation may prime donor T cells to mediate cutaneous graft-versus-host disease (GVHD). This possible association, however, has not been investigated in the setting of nonmyeloablative allografting. Methods We prospectively studied the kinetics of LC-chimerism after sex-mismatched allogeneic hematopoietic cell transplantation with nonmyeloablative (n=23) or myeloablative (n=25) conditioning. Combined XY-FISH and Langerin-staining was used to assess donor LC-chimerism in skin biopsies obtained on days 28, 56, and 84 after transplant. The degree of donor LC-chimerism was correlated with the development of skin GVHD. Results We observed significantly delayed donor LC-engraftment after nonmyeloablative transplantation compared with other hematopoietic compartments and compared with LC-engraftment after myeloablative conditioning. In most recipients of nonmyeloablative transplants, recipient LCs proliferated in situ, recruitment of donor-LCs was delayed by two months, and full donor LC-chimerism was only reached by day 84 after transplant. Although persistence of host LCs on day-28 after transplant was not predictive for acute or chronic skin GVHD, the recruitment of donor-derived LCs was associated with nonspecific inflammatory infiltrates (P=0.009). Conclusions These results show that LCs can self-renew locally but are replaced by circulating precursors even after minimally toxic nonmyeloablative transplant conditioning. Cutaneous inflammation accompanies donor LC-engraftment, but differences in LC conversion-kinetics do not predict clinical or histopathological GVHD.

Abstract B79: Detectable BRAF-V600E mutation in circulating peripheral blood of patients with Langerhans cell histiocytosis correlates with risk organ involvement and residual disease

NATURE IMMUNOLOGY VOLUME 17 NUMBER 4 APRIL 2016 345 suppressive effects of radiation and/or enhance its immune system–promoting effects. For example, clinical radiotherapy can be successfully combined with blockade of immunological checkpoints that counteracts a radiation-induced increase in Treg cells8. Moreover, evidence is emerging that local radiation therapy can convert a tumor into an individualized cancer vaccine in a setting of otherwise ineffective immunotherapy and can work in concert with immunotherapy to control the primary tumor and metastasis outside the radiation field9,10.

Tissue-resident macrophages self-maintain locally throughout adult life with minimal contribution from circulating monocytes.

Purpose: Langerhans Cell Histiocytosis (LCH) is a clonal disorder characterized by inflammatory lesions with characteristic CD207+ dendritic cells (DCs). LCH has variable clinical presentations ranging from single lesions to potentially fatal multi-system “risk organ” disease. The etiology of LCH remains elusive, with debate of LCH as an inflammatory versus malignant disorder unresolved. The first recurrent somatic genetic mutation in LCH, BRAF-V600E, was recently reported in 57% of LCH lesions (Badalian-Very et al., 2010). Here we investigate the clinical significance of BRAF-V600E as a potential biomarker of risk organ or refractory disease. Methods: Formalin-fixed, paraffin embedded (FFPE) tissue, peripheral blood, and sorted peripheral monocyte/dendritic cell populations were genotyped for BRAF-V600E mutations with allele-specific, real-time PCR assays. The presence of BRAF-V600E mutations was correlated with clinical variables and analyzed with standard statistical methods. A subsequent validation set of 8 patient peripheral blood samples was identified for quantitative analysis of levels of BRAF-V600E positive cells with the BRAF Rotor-Gene Q (RGQ) PCR assay (Qiagen, Valencia, CA), and concordance with results from Qiagen qBiomarker qPCR assay was determined. Quantitation was performed using a delta Ct method of the BRAF-V600E assay, and results were reported as percentage of mutant cells in a background of wild-type cells using standard curves. Results: Lesions from 100 patients with LCH were genotyped, and 64% carried the V600E mutation, which localized to the infiltrating CD207+ DCs. In 16 patients with more than one lesion, BRAF status remained fixed, suggesting somatic mutation of BRAF is an early event. BRAF-V600E did not define specific clinical risk groups or impact overall survival, but it was associated with approximately two-fold higher risk of relapse (p=0.04). Furthermore, the cellular compartment carrying the mutation correlated with disease severity: the ability to detect BRAF-V600E in circulating mononuclear cells defined risk organ LCH with 100% sensitivity/87% specificity. The ability to detect BRAF-V600E in circulating blood cells in patients with risk organ LCH defined clinically detectable disease with 97% sensitivity/100% specificity. For development of a clinically reproducible minimal residual disease assay that would be CLIA-compliant and commercially available, a separate validation sample set was identified. With a limit of detection of 0.02% mutant cells in a background of wild-type cells, the RGQ assay correctly detected BRAF-V600E mutations in all 8 validation specimens and in known BRAF-V600E positive cell lines and did not detect mutations in 10 additional BRAF-V600E mutation negative clinical specimens (analytical specificity = 100%). The RGQ quantitative results correlated with the qBiomarker assay results (R2=0.924) with comparable analytical sensitivity. Conclusions: The molecular foothold of BRAF at the base of LCH pathogenesis will allow therapeutic strategies to move beyond empiric observation to risk-stratified and targeted approaches. Furthermore, effectiveness of therapy may be tested by following BRAF-V600E in peripheral blood cells as a marker of residual disease. Development of validated assays to test for BRAF-V600E in peripheral blood will assist in assigning risk status and assessing therapeutic response. Citation Format: Stephen J. Simko, Marie-Luise Berres, Karen Phaik-Har Lim, Tricia Peters, Jeremy Price, Philip J. Lupo, M. John Hicks, Albert Shih, Kenneth Heym, Kenneth L. McClain, Miriam Merad, Stephen Sarabia, Dolores Lopez-Terrada, Carl E. Allen. Detectable BRAF-V600E mutation in circulating peripheral blood of patients with Langerhans cell histiocytosis correlates with risk organ involvement and residual disease. [abstract]. In: Proceedings of the AACR Special Conference on Pediatric Cancer at the Crossroads: Translating Discovery into Improved Outcomes; Nov 3-6, 2013; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2013;74(20 Suppl):Abstract nr B79.