Exome ICE sequencing Methods_The Broad Institute v1

Here we describe the Exome ICE Method followed by The Broad Genomics Platform for sequencing genomic DNA from human biospecimens for the Human Atlas Pilot Project (HTAPP). During the years, modifications were introduced to the method resulting in slightly different versions employed. Below we provide the description of the three different versions used on HTAPP samples (from newer to older) highlighting their differences in bold lettering.

Transcriptome Capture Sequencing Method_The Broad Institute v1

Here we describe the Transcriptome Capture Method followed by The Broad Genomics Platform for sequencing bulk RNA from human biospecimens for the Human Atlas Pilot Project (HTAPP). This protocol is usually utilized for Formalin Fixed Paraffin Embedded (FFPE) samples, although it can also be used for non-FFPE samples, as was the case for some HTAPP samples.

Stranded RNA-Sequencing Method_The Broad Institute v1

Here we describe the TruSeq Strand Specific Large Insert Method followed by The Broad Genomics Platform to sequence bulk RNA from human tumor biospecimens for the Human Tumor Atlas Pilot Project (HTAPP). During the years, modifications were introduced to the method resulting in slightly different versions employed. Below we provide the description of the three different versions used on HTAPP samples (from newer to older) highlighting their differences in bold lettering.

Identity of Applicants for Priority Rights and the EPO’s CRISPR-Cas/Broad Institute Decision T 0844/18 ‒ Scope of the EPO’s ‘Formal Review’ to Establish Identity of the Holder of the Priority Right

The Technical Board of Appeal 3.3.08 (hereinafter ‘the Board’) has handed down the much-awaited written decision regarding the denial of the CRISPR/Cas9 patent EP2771468. The Board did not acknowledge the patentee’s claim to priority from a provisional US application naming more applicants than the subsequent Patent Cooperation Treaty (PCT) application from which the European patent was derived. The Board considered the priority claim invalid because there was no identity between the applicants of the prior and subsequent application. This article does not second-guess the ‘all applicants’ approach as confirmed by the Board, but considers the consequences of the decision for the claiming of priority by the ‘same applicants’

Exploiting the DepMap cancer dependency data using the depmap R package

The `depmap` package facilitates access in the R environment to the data from the DepMap project, a multi-year collaborative effort by the Broad Institute and Wellcome Sanger Institute, mapping genetic and chemical dependencies and other molecular biological measurements of over 1700 cancer cell lines. The 'depmap' package formats this data to simply the use of popular R data analysis and visualizing tools such as 'dplyr' and 'ggplot2'. In addition, the 'depmap' package utilizes 'ExperimentHub', storing versions of the DepMap data accessible from the Cloud, which may be selectively downloaded, providing a reproducible research framework to support exploiting this data. This paper describes a workflow demonstrating how to access and visualize the DepMap data in R using this package.

Formal Methods for the Informal Engineer: Workshop Recommendations

Formal Methods for the Informal Engineer (FMIE) was a workshop held at the Broad Institute of MIT and Harvard in 2021 to explore the potential role of verified software in the biomedical software ecosystem. The motivation for organizing FMIE was the recognition that the life sciences and medicine are undergoing a transition from being passive consumers of software and AI/ML technologies to fundamental drivers of new platforms, including those which will need to be mission and safety-critical. Drawing on conversations leading up to and during the workshop, we make five concrete recommendations to help software leaders organically incorporate tools, techniques, and perspectives from formal methods into their project planning and development trajectories.

SARS-CoV-2 Antibody persistence in COVID-19 convalescent plasma donors

Background Antibody response duration following SARS-CoV-2 infection tends to be variable and depends on severity of disease and method of detection. Study design and methods COVID-19 convalescent plasma (CCP) from 18 donors was collected longitudinally for a maximum of 63 - 129 days following resolution of symptoms. All the samples were initially screened by the Ortho Total Ig test to confirm positivity and subsequently tested with 7 additional direct sandwich or indirect binding assays (Ortho, Roche, Abbott, Broad Institute) directed against a variety of antigen targets (S1, RBD, and NC), along with 2 neutralization assays (Broad Institute live virus PRNT and Vitalant Research Institute Pseudovirus RVPN). Results The direct detection assays (Ortho Total Ig total and Roche Total Ig) showed increasing levels of antibodies over the time period, in contrast to the indirect IgG assays that showed a decline. Neutralization assays also demonstrated declining responses; the VRI RVPN pseudovirus had a greater rate of decline than the Broad PRNT live virus assay. Discussion These data show that in addition to variable individual responses and associations with disease severity, the detection assay chosen contributes to the heterogeneous results in antibody stability over time. Depending on the scope of the research, one assay may be preferable over another. For serosurveillance studies, direct, double Ag-sandwich assays appear to be the best choice due to their stability; in particular, algorithms that include both S1 and NC based assays can help reduce the rate of false-positivity and discriminate between natural infection and vaccine-derived seroreactivity.

Exploiting the Zinc Finger Degrome Targeted By Lenalidomide to Engineer Reversible Off-Switch Degradable Chimeric Antigen Receptors

Cell-based therapies are emerging as potent agents against cancer and other diseases, but are uniquely uncontrolled "living drugs". For example, chimeric antigen receptor (CAR) T cells can effectively target hematologic malignancies yet pose a risk for toxic hyperactivation. Future cell-based therapies, including CAR T cells, could be improved by incorporating specific and reversible control systems. However, clinically suitable ON- and OFF-switches engineered from non-immunogenic human polypeptide sequences and regulated by non-immunosuppressive FDA-approved drugs are needed. Here we report the engineering of a robust lenalidomide-responsive degron tag, which we then used to construct a degradable CAR affording reversible OFF-switch functional control at clinically relevant lenalidomide doses. Thalidomide, lenalidomide, and pomalidomide are effective and clinically approved therapies for multiple myeloma, subtypes of non-Hodgkin lymphoma, and myelodysplastic syndrome with chromosome 5q deletion. These drugs exert therapeutic properties by acting as molecular glue, bridging interactions between the CRL4CRBN ubiquitin ligase and disease-relevant proteins that are subsequently ubiquitinated and degraded by the proteasome. A set of Cys2-His2 (C2H2) zinc fingers have emerged as degron motifs mediating drug-dependent interactions with the CRL4CRBN ubiquitin ligase. We hypothesized that these small, modular, human polypeptide domains could be further engineered and repurposed as tags to induce drug-dependent depletion of engineered proteins. By systematically shuffling the subdomains of all known zinc finger degrons and functionally screening this hybrid zinc finger library, we engineered "super-degron" tags that are more efficiently degraded at lower drug concentrations than any C2H2 zinc finger in the human proteome. We then incorporated one of these super-degrons (SD01) into a second-generation CAR targeting CD19 (FMC63-4-1BB-CD3z), thereby constructing a degradable CAR (Figure 1A). In a Jurkat T cell model, addition of lenalidomide induced rapid and near-complete depletion of the degradable CAR (Figure 1B/C). When co-cultured with target cells expressing CD19, therapeutically relevant lenalidomide concentrations robustly inhibited T cell activation (Figure 1D). Indeed, the IC50 for inhibition of IL2 secretion and CD69 expression were 2 and 22 nM lenalidomide, respectively, whereas in myeloma patients the plasma concentration of lenalidomide following one 25 mg oral dose decays from ~1000 to 10 nM over the course of 24 hours (Connarn et al, CPDD, 2017). In primary T cells, 100 nM lenalidomide suppressed degradable CAR effector functions including tumor cell killing and cytokine release (Figure 1E). Using pomalidomide, which has a longer in vivo half-life, we demonstrated robust and reversible depletion of the degradable CAR in T cells engrafted in NSG mice. Together, these findings demonstrate reversible OFF-switch control of degradable CARs at clinically relevant lenalidomide concentrations. Experiments are underway to determine whether, in the context of tumor clearance in NSG mice, degradable CAR T cell effector functions can be paused and subsequently released with short-term administration of lenalidomide. Whereas the current management of CAR T cell hyperactivation syndromes consists of supportive care, tocilizumab, and/or high-dose corticosteroids, we propose that cytokine release and CAR-related encephalopathy syndromes may be more easily diagnosed and managed with degradable CARs. The super-degron tags presented here are generalizable and clinically suitable tools to achieve chemical genetic control of diverse genetically engineered cell therapies. Disclosures Jan: Broad Institute: Other: Contributor to a patent filing on this technology that is held by the Broad Institute.. Sievers:Broad Institute: Other: Contributor to a patent filing on this technology that is held by the Broad Institute.. Maus:Broad Institute: Other: Contributor to a patent filing on this technology that is held by the Broad Institute.. Ebert:Broad Institute: Other: Contributor to a patent filing on this technology that is held by the Broad Institute.; Deerfield: Research Funding; Celgene: Research Funding.

Deconstructing the Clonal Advantage and Clonal Stability of 5q- Candidate Genes in Del(5q) MDS on a Single Cell Level

Hematopoietic Stem/Progenitor cells (HSPCs) with 5q haploinsufficiency in del(5q) myelodysplastic syndrome (MDS) acquire a clonal advantage in the bone marrow and out-compete normal hematopoiesis. A critical, yet unsolved question remains: how does genetic haploinsufficiency in del(5q) cells contribute to the clonal advantage of HSPCs? We investigated the role of haploinsufficiency for three candidate genes in the common deleted region on chromosome 5 (Csnk1a1, Egr1 and Apc) in direct competition with each other and wild-type (wt) cells on a single cell level by employing a novel lentiviral genetic barcoding strategy. We introduced genotype and cell-specific barcodes into HSPCs from murine models haploinsufficient for Csnk1a1, Egr1 or Apc. Barcoded HSPCs were sort-purified, genotypes mixed and subsequently competitively transplanted into lethally irradiated mice and re-transplanted after 16 weeks in a secondary transplant. The barcoded progeny was reliably recovered from peripheral blood and relative contribution of the barcoded clones to differentiated blood lineages was followed over 32 weeks. Despite heterogeneity in clonal evolution among the mice, all haploinsufficient clones had the potential to outcompete wt clones (3 of 5 mice in the primary transplant, 3 out of 4 mice in the secondary transplant). Csnk1a1 haploinsufficient clones showed the largest clonal abundance and clonal persistence. Expansion of oligoclonal Csnk1a1 haploinsufficient HSPCs was further enhanced in the secondary transplant in all mice. Egr1 haploinsufficient clones showed potential for prominent oligoclonal expansion in one mouse, but decreased in abundance in all secondary transplants. Apc haploinsufficient clones showed persistence but not expansion in 3 out of 5 mice. These results were validated by conventional competitive transplants, which demonstrated that Csnk1a1 and Egr1 haploinsufficient cells achieved the highest advantage over wt hematopoiesis in the primary transplant and more enhanced in the secondary transplant. Since Csnk1a1 regulates β-catenin protein stability, we hypothesized that the clonal expansion of Csnk1a1 haploinsufficient HSPCs is dependent on β-catenin levels. We performed a second genetic barcoding competitive transplant, comparing Csnk1a1-/+ HSPC directly to double haploinsufficient Csnk1a1-/+/Ctnnb1-/+ (β-catenin encoding) HSPCs. We included additional double haploinsufficient mutants Csnk1a1-/+/Apc-/+ and Csnk1a1-/+/Egr1-/+. Results showed pronounced expansion of Csnk1a1-/+ clones, while Csnk1a1-/+/Ctnnb1-/+ clones were outcompeted over time, suggesting that the advantage of Csnk1a1-/+ clones is β-catenin dependent. Csnk1a1-/+/Egr1-/+ and Csnk1a1-/+/Apc-/+ clones were less advantageous than Csnk1a1-/+ clones. To further investigate the mechanism of clonal fitness in Csnk1a1-/+ haploinsufficient HSPCs, we performed droplet based single cell RNA sequencing of Csnk1a1-/+ and wt Lin-Sca1+cKit+ (LSK) HSPCs. Csnk1a1 -/+ LSK were characterized by a higher fraction of cells expressing cell cycle genes compared to wt cells. In line, transcriptional alterations in the most primitive HSCs suggest that the clonal advantage is conveyed by canonical Wnt signaling activating downstream targets such E2F proteins. Csnk1a1-/+ haploinsufficient multipotent progenitors and myeloid/lymphoid primed progenitors expressed marked upregulation of metabolic pathways, mitochondrial respiration, cell cycle and differentiation, ubiquitination/proteasome system and deregulation of ribosome biogenesis. In conclusion, we demonstrate using a novel genetic barcoding approach in a competitive transplant setting that Csnk1a1-/+ haploinsufficient HSPCs have the potential for oligoclonal expansion and clonal persistence. Wnt/β-catenin signaling plays a central role in the clonal expansion. Interestingly, in Csnk1a1 haploinsufficiency the HSC state is preserved and the increased proliferation and metabolic activation are hallmark features of differentiating progenitor cells at MPP stage, increasing with cell cycle activation, thus ensuring clonal stability and preventing HSC exhaustion over time. Disclosures Brümmendorf: University Hospital of the RWTH Aachen: Employment; Janssen: Consultancy; Pfizer: Consultancy, Research Funding; Merck: Consultancy; Novartis: Consultancy, Research Funding; Ariad: Consultancy. Ebert:Celgene: Research Funding; Deerfield: Research Funding; Broad Institute: Other: Contributor to a patent filing on this technology that is held by the Broad Institute..