Chromosomal instability and associated chromosomal aberrations are hallmarks of cancer and play a critical role in disease progression and development of resistance to drugs. Single-cell genome ...analysis has gained interest in latest years as a source of biomarkers for targeted-therapy selection and drug resistance, and several methods have been developed to amplify the genomic DNA and to produce libraries suitable for Whole Genome Sequencing (WGS). However, most protocols require several enzymatic and cleanup steps, thus increasing the complexity and length of protocols, while robustness and speed are key factors for clinical applications. To tackle this issue, we developed a single-tube, single-step, streamlined protocol, exploiting ligation mediated PCR (LM-PCR) Whole Genome Amplification (WGA) method, for low-pass genome sequencing with the Ion Torrent™ platform and copy number alterations (CNAs) calling from single cells. The method was evaluated on single cells isolated from 6 aberrant cell lines of the NCI-H series. In addition, to demonstrate the feasibility of the workflow on clinical samples, we analyzed single circulating tumor cells (CTCs) and white blood cells (WBCs) isolated from the blood of patients affected by prostate cancer or lung adenocarcinoma. The results obtained show that the developed workflow generates data accurately representing whole genome absolute copy number profiles of single cell and allows alterations calling at resolutions down to 100 Kbp with as few as 200,000 reads. The presented data demonstrate the feasibility of the Ampli1™ WGA-based low-pass workflow for detection of CNAs in single tumor cells which would be of particular interest for genome-driven targeted therapy selection and for monitoring of disease progression.
Precision medicine in oncology requires an accurate characterization of a tumor molecular profile for patient stratification. Though targeted deep sequencing is an effective tool to detect the ...presence of somatic sequence variants, a significant number of patient specimens do not meet the requirements needed for routine clinical application. Analysis is hindered by contamination of normal cells and inherent tumor heterogeneity, compounded with challenges of dealing with minute amounts of tissue and DNA damages common in formalin-fixed paraffin-embedded (FFPE) specimens. Here we present an innovative workflow using DEPArray™ system, a microchip-based digital sorter to achieve 100%-pure, homogenous subpopulations of cells from FFPE samples. Cells are distinguished by fluorescently labeled antibodies and DNA content. The ability to address tumor heterogeneity enables unambiguous determination of true-positive sequence variants, loss-of-heterozygosity as well as copy number variants. The proposed strategy overcomes the inherent trade-offs made between sensitivity and specificity in detecting genetic variants from a mixed population, thus rescuing for analysis even the smaller clinical samples with low tumor cellularity.
Sorting and recovering specific live cells from samples containing less than a few thousand cells have become major hurdles in rare cell exploration such as stem cell research, cell therapy and cell ...based diagnostics. We describe here a new technology based on a microelectronic chip integrating an array of over 100,000 independent electrodes and sensors which allow individual and parallel single cell manipulation of up to 10,000 cells while maintaining viability and proliferation capabilities. Manipulation is carried out using dynamic dielectrophoretic traps controlled by an electronic interface. We also demonstrate the capabilities of the chip by sorting and recovering individual live fluorescent cells from an unlabeled population.
Several hundred clinical trials currently explore the role of circulating tumor cell (CTC) analysis for therapy decisions, but assays are lacking for comprehensive molecular characterization of CTCs ...with diagnostic precision. We therefore combined a workflow for enrichment and isolation of pure CTCs with a non‐random whole genome amplification method for single cells and applied it to 510 single CTCs and 189 leukocytes of 66 CTC‐positive breast cancer patients. We defined a genome integrity index (GII) to identify single cells suited for molecular characterization by different molecular assays, such as diagnostic profiling of point mutations, gene amplifications and whole genomes of single cells. The reliability of > 90% for successful molecular analysis of high‐quality clinical samples selected by the GII enabled assessing the molecular heterogeneity of single CTCs of metastatic breast cancer patients. We readily identified genomic disparity of potentially high relevance between primary tumors and CTCs. Microheterogeneity analysis among individual CTCs uncovered pre‐existing cells resistant to ERBB2‐targeted therapies suggesting ongoing microevolution at late‐stage disease whose exploration may provide essential information for personalized treatment decisions and shed light into mechanisms of acquired drug resistance.
Synopsis
A novel workflow enabling detection, isolation and characterization of single circulating tumors cells (CTCs) from blood suggests that CTCs may harbor genetic alterations undetectable in the primary tumor and associated with therapy resistance.
Single circulating tumor cells (CTCs) are analyzed by a semi‐automated workflow combining CellSearch® enrichment, DEPArrayTM isolation and Ampli1TM whole genome amplification (WGA).
The WGA quality of single CTCs is assessed by a genome integrity index (GII).
The GII predicts outcome of downstream sequence‐based molecular assays.
Single cell analysis reveals the existence of rare potential therapy escape variants.
The diagnostic precision of the workflow enables molecular monitoring of CTCs under iatrogenic selection.
A novel workflow enabling detection, isolation and characterization of single circulating tumors cells (CTCs) from blood suggests that CTCs may harbor genetic alterations undetectable in the primary tumor and associated with therapy resistance.
Manipulation of populations of living cells on an individual basis is essential for the investigation of complex interactions among cells. We present a new approach to the integration on silicon of ...dielectrophoretic actuators and optical sensors that allow us to carry out this task. The device presented in this paper is an 8/spl times/8 mm/sup 2/ chip implemented in a two-poly three-metal 0.35-/spl mu/m CMOS technology, featuring 102,400 actuation electrodes, arranged in an array of 320/spl times/320, 20 /spl mu/m/spl times/20/spl mu/m microsites each comprising addressing logic, an embedded memory for electrode programming, and an optical sensor. The chip enables software-controlled displacement of more than 10,000 individual living cells, allowing biologists to devise complex interaction protocols that are impossible to manage otherwise. The manipulation does not damage the viability of the cells, so that this approach could be a unique extension to the techniques already available to biologists.
Introduction
Immune-checkpoint blockade has emerged as an effective therapeutic strategy in solid tumor and in hematologic malignancies, including classical Hodgkin Lymphoma (cHL).
cHL represents ...about 11% of all malignant lymphoma and it is generally highly curable with standard frontline therapies, although about 20% of the patients will relapse or become refractory after initial treatment.
The hallmark of cHL is the presence of malignant Hodgkin and Reed-Sternberg Cells (HRS) that represent only a small fraction (about 1%) of the surrounding heterogeneous immune infiltrate. Despite this extensive inflammatory microenvironment, HRS are able to escape immune surveillance using several mechanisms, including the overexpression of PD-1 ligands (PD-Ls) that bind PD-1 on reactive T-cells, inhibiting their activity and proliferation and causing ultimately T-cell exhaustion. The PD-Ls expression is upregulated in a dose-dependent manner by copy number alterations of chromosome 9p24.1, a locus encoding for PD-L1/PD-L2 as well as JAK2, which further enhances PD-Ls expression through JAK2/STAT pathway.
Here we present a method for the isolation and the genetic characterization of single purified HRS, which overcomes the limitations posed by the low tumor cellularity of cHL biopsies and gives an estimation of inter-tumor and intra-tumor heterogeneity which may be useful to guide immune treatment selection.
Methods
FFPE tissue sections from 4 cHL patients were dissociated down to single-cell suspension and stained using anti-CD30 and anti-PD-L1 antibodies. Since CD30 is not expressed exclusively by malignant cells, beyond the positivity to CD30 and PD-L1 HRS were selected according to morphological criteria, such as cell size and the presence of nuclei with ploidy higher than the surrounding lymphocytes.
DEPArray™ NxT system (Menarini Silicon Biosystems) was used to isolate single target cells. After recovery, single cells were whole genome amplified (Ampli1™ WGA, Menarini Silicon Biosystems), and genome-wide copy-number alterations (CNAs) profiles were obtained using Ampli1™ LowPass kits (Menarini Silicon Biosystems) on Illumina® and Ion Torrent™ platforms.
Results
For each patient, at least 8 HRS cells and infiltrating lymphocytes were identified and isolated from lymphoid tissue using DEPArray™ NxT system.
Copy-number analyses of recovered cells allowed us to precisely discriminate HRS, characterized by extensive gains and losses, from non-tumor cells, showing flat profiles as expected (Fig.1). Ploidy of HRS was automatically determined, based on best-fitting of profiles with underlying copy number levels.
Hierarchical clustering showed that some alterations are highly conserved among patients, e.g. the region containing PD-L1/PD-L2/JAK2 has several copy gains in the majority of malignant cells. Interestingly, these alterations show high variable copy-number levels between different HRS even in the same patient, ranging from few copy-gains to amplifications, suggesting some level of heterogeneity.
Different CNAs are also detected in regions containing genes belonging to pathways already known to be altered in cHL, like REL/NFKB and JAK/STAT pathways, which may be involved in the constitutive activation of proliferative and antiapoptotic phenotype of HRS.
Conclusion
Single HRS sorting combined with low-pass whole genome sequencing offer a valuable tool to uncover genetic alterations hidden by the massive cHL immune infiltrate and to estimate inter-tumor and intra-tumor heterogeneity in cHL patients. Considering that PD-Ls locus amplifications are associated with advanced stages of the disease and with a shorter progression free survival, the analysis of purified HRS could be helpful for patient stratification for the adoption of immune therapy.
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Mangano:Menarini Silicon Biosystems: Employment. Edoardo:Menarini Silicon Biosystems: Employment. Garonzi:Menarini Silicon Biosystems: Employment. Lanzellotto:Menarini Silicon Biosystems: Employment. Papadopulos:Menarini Silicon Biosystems: Employment. Bolognesi:Menarini Silicon Biosystems: Employment. Buson:Menarini Silicon Biosystems: Employment. Ferrarini:Menarini Silicon Biosystems: Employment. Forcato:Menarini Silicon Biosystems: Employment. Fontana:Menarini Silicon Biosystems: Employment. Ceccolini:Istituto Scientifico Romagnolo per lo Studio e la Cura dei Tumori (IRST) IRCCS: Employment. Fabbri:Istituto Scientifico Romagnolo per lo Studio e la Cura dei Tumori (IRST) IRCCS: Employment. Fici:Istituto Scientifico Romagnolo per lo Studio e la Cura dei Tumori (IRST) IRCCS: Employment. Gallerani:Istituto Scientifico Romagnolo per lo Studio e la Cura dei Tumori (IRST) IRCCS: Employment. Simonelli:Menarini Silicon Biosystems: Employment. Medoro:Menarini Silicon Biosystems: Employment. Manaresi:Menarini Silicon Biosystems: Employment.
Introduction: Multiple myeloma (MM) is a malignancy of terminally differentiated plasma cells. The high heterogeneity of MM cells is one of the major cause of disease relapse. Detection of ...circulating MM cells (CMMC) from peripheral blood is a useful procedure to investigate tumor heterogeneity and provides a painless alternative to the classic bone marrow biopsy to monitor disease progression. Here we demonstrate that the synergy between CellSearch® (CS) and DEPArray™ (DA) technologies can be used to identify, isolate and characterize at the genetic level single and pure CMMCs .
Methods: 4.0 ml of peripheral blood samples were obtained from 3 patients with MM. Putative CMMCs were enriched with CS using anti-CD138 or anti-CD138/CD38 as positive selection marker and subsequently stained with CD38-PE, CD19/CD45-APC immunofluorescent probes. Cells detection and enumeration was performed based on the co-localization of nuclei DAPI staining and CD38-PE. Single CMMCs (CD38+/CD19- and CD45-/DAPI+) and White Blood Cells (WBCs: CD38-/CD19+ or CD45+/DAPI+) were then isolated using the DA NxT system. Single cells genomic DNA was amplified using Ampli1™ Whole Genome Amplification (WGA) kit and Illumina®-compatible libraries were obtained using Ampli1™ LowPass kit and a high-throughput, customized automated protocol using Hamilton STARLet Liquid handler. Highly-multiplexed, genome-wide single-cell Low-Pass Copy Number Alteration (LPCNA) analysis was performed using HiSeq 2500 Illumina® platform.
Results: CS and DA workflow* enabled the isolation of 215 single CMMC, selected for LPCNA analysis. 42 single WBCs were also included as normal controls. Copy-number profiles of single CMMCs showed relevant gains and losses of chromosomal segments, as result of a high-level genomic instability. Notably, intra-patient CMMCs revealed overall conserved CNA patterns with subclonal alterations, suggesting a certain level of branched tumor evolution. Conversely, a higher degree of heterogeneity in CMMCs CNA profiles was observed among different patients. Interestingly, CNAs detected in all patients are located in regions containing genes involved in cell cycle regulation (MAPK, NOTCH pathways) and cell signaling (IL6R), which might be involved in proliferative processes and immuno-surveillance escape.
Conclusion: The combination of CS and DA workflow* with a streamlined automated protocol allowed to obtain hundreds of genomic libraries from pure single CMMCs. The presented workflow constitutes a non-invasive, rapid and high-throughput approach for characterizing MM tumor heterogeneity and progression, suggesting a possible future implementation in clinical applications.
*For Research Use Only. Not for use in diagnostic procedures.
Raspadori:Menarini Silicon Biosystems: Employment. Forcato:Menarini Silicon Biosystems: Employment. Edoardo:Menarini Silicon Biosystems: Employment. Papadopulos:Menarini Silicon Biosystems: Employment. Ferrarini:Menarini Silicon Biosystems: Employment. Del Monaco:Menarini Silicon Biosystems: Employment. Terracciano:Menarini Silicon Biosystems: Employment. Morano:Menarini Silicon Biosystems: Employment. Gross:Menarini Silicon Biosystems: Employment. Bolognesi:Menarini Silicon Biosystems: Employment. Buson:Menarini Silicon Biosystems: Employment. Fontana:Menarini Silicon Biosystems: Employment. Connelly:Menarini Silicon Biosystems, Inc.: Employment, Other: Chief R&D Officer, USA. Simonelli:Menarini Silicon Biosystems: Employment. Medoro:Menarini Silicon Biosystems: Employment. Manaresi:Menarini Silicon Biosystems: Employment.
Manipulating single biological objects is a major unmet challenge of biomedicine. Herein, we describe a lab-on-a-chip platform based on dielectrophoresis (DEP). The DEParray is a prototypal version ...consisting of 320 × 320 arrayed electrodes generating >10 000 spherical DEP cages. It allows the capture and software-guided movement to predetermined spatial coordinates of single biological objects. With the DEParray we demonstrate (a) forced interaction between a single, preselected target cell and a programmable number of either microspheres or natural killer (NK) cells, (b) on-chip immunophenotypic discrimination of individual cells based on differential rosetting with microspheres functionalized with monoclonal antibodies to an inhibitory NK cell ligand (HLA-G), (c) on-chip, real-time (few minutes) assessment of immune lysis by either visual inspection or semiautomated, time-lapse reading of a fluorescent dye released from NK cell-sensitive targets, and (d) manipulation and immunophenotyping with limiting amounts (about 500) cells. To our knowledge, this is the first report describing a DEP-based lab-on-a-chip platform for the quick, arrayed, software-guided binding of individually moved biological objects, the targeting of single cells with microspheres, and the real-time characterization of immunophenotypes. The DEParray candidates as a discovery tool for novel cell:cell interactions with no prior (immuno)phenotypic knowledge.
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