Functional Multi-Omics Reveals Genetic and Pharmacologic Regulation of Surface CD38 in Multiple Myeloma

Background: CD38 is a surface ectoenzyme expressed at high levels on myeloma plasma cells and is the target for the monoclonal antibodies (mAbs) daratumumab and isatuximab. These antibodies have multiple mechanisms of action, primarily involving recruiting and modulating components of the immune system, but they may also carry direct anti-tumor effects. CD38 density on tumor cells is an important determinant of mAb efficacy while CD38 is lost after mAb treatment. Several small molecules have been found to increase tumor surface CD38, with the goal of boosting mAb efficacy in a co-treatment strategy. However, we do not yet have a broad global sense of the transcriptional or post-transcriptional networks that most strongly impact CD38 expression. There may be alternate strategies to even more potently increase CD38 expression that have not yet been identified. Furthermore, prior clinical studies showed that CD38 downregulation after daratumumab treatment was accompanied by increases in the complement inhibitors CD55 and CD59. Are there other features of myeloma surface remodeling driven by CD38 downregulation? Here we sought to extend our currently limited insight into CD38 surface expression by using a multi-omics approach. Methods: Genome-wide CRISPR interference screening was performed in RPMI-8226 cells stably expressing the dCas9-KRAB fusion protein. Cells were grown for 14 days after library transduction, flow-sorted on the top and bottom 25% of CD38 surface expression, and sgRNA's deep sequenced. Antibody-dependent cellular cytoxicity assays were performed with NK92-CD16 cells. Cell surface proteomics was performed using N-glycoprotein cell surface capture in triplicate. Phosphoproteomics was performed used immobilized metal affinity chromatography in triplicate. Murine studies were performed in NSG mice under approved IACUC-approved institutional protocols. Results: A genome-wide CRISPR-interference screen in RPMI-8226 cells demonstrated that transcriptional and epigenetic factors played the most prominent role in surface CD38 regulation (Fig. 1A). One of the genes that when knocked down led to greatest surface CD38 increase was RARA. This finding supports the promise of all-trans retinoic acid (ATRA), which leads to RARA degradation, as a potent agent to induce CD38 upregulation. Validation of additional screen hits TLE3 and HEXIM1 also illustrated that these negative regulatory transcription factors suppress CD38 expression at baseline (not shown). We found the transcription factor SPI1 to be a prominent positive regulator of CD38. SPI1 knockdown led to daratumumab resistance both in vitro and in vivo, similar to the resistance observed after CD38 knockdown (not shown). Analysis of myeloma patient ATAC-seq data, assessing transcription factor motifs present at the CD38 locus, combined with a predictive machine learning model, further identified XBP1 as one of the most potent transcriptional regulators of CD38 (Fig. 1B). We next used "antigen escape profiling" - knockdown of CD38 followed by unbiased cell surface proteomics - to mimic surface alterations in the context of CD38 loss. We found minimal changes in other cell surface proteins beyond CD38 (Fig. 1C), indicating the CD38 loss alone is not sufficient to remodel the myeloma surfaceome. This finding also supports the hypothesis that complement or other immune system interactions are necessary to lead to other myeloma surface protein alterations. In a parallel analysis of pharmacologic regulation, we also used cell surface proteomics integrated with RNA-seq to demonstrate that ATRA leads to few other surface protein changes beyond CD38 (not shown). In contrast, other molecules, such as azacytidine and panobinostat, led to broader changes across many more surface proteins, showing a lack of specificity when driving CD38 upregulation. Finally, unbiased phosphoproteomics revealed partial inhibition of the MAP kinase pathway after daratumumab binding (Fig. 1D). This result may comprise a direct anti-proliferative effect of anti-CD38 therapeutic antibody engagement in myeloma. Conclusions: Our work provides a resource to design strategies to enhance efficacy of CD38-targeting immunotherapies in myeloma. Our approach also outlines a broad multi-omic strategy to evaluate surface and transcriptional regulation of other key immunotherapeutic targets in hematologic malignancies. Figure 1 Figure 1. Disclosures Choudhry: Genentech: Current Employment, Current equity holder in publicly-traded company. Ramkumar: Senti Biosciences: Current Employment, Current holder of individual stocks in a privately-held company.

The pulmonary vascular bed in patients with functionally univentricular physiology and a Fontan circulation

Fontan palliation represents one of the most remarkable surgical advances in the management of individuals born with functionally univentricular physiology. The operation secures adult survival for all but a few with unfavourable anatomy and/or physiology. Inherent to the physiology is passive transpulmonary blood flow, which produces a vulnerability to adequate filling of the systemic ventricle at rest and during exertion. Similarly, the upstream effects of passive flow in the lungs are venous congestion and venous hypertension, especially marked during physical activity. The pulmonary vascular bed has emerged as a defining character on the stage of Fontan circulatory behaviour and clinical outcomes. Its pharmacologic regulation and anatomic rehabilitation therefore seem important strategic therapeutic targets. This review seeks to delineate the important aspects of pulmonary artery development and maturation in functionally univentricular physiology patients, pulmonary artery biology, pulmonary vascular reserve with exercise, and pulmonary artery morphologic and pharmacologic rehabilitation.

Functional multi-omics reveals genetic and pharmacologic regulation of surface CD38 in multiple myeloma

CD38 is a surface ectoenzyme expressed at high levels on myeloma plasma cells and is the target for the monoclonal antibodies (mAbs) daratumumab and isatuximab. CD38 density on tumor cells is an important determinant of mAb efficacy, and CD38 loss after mAb treatment may play a role in resistance. Several small molecules have been found to increase tumor surface CD38, with the goal of boosting mAb efficacy in a co-treatment strategy. Here we sought to extend our currently limited insight into CD38 surface expression by using a multi-omics approach. Genome-wide CRISPR-interference screens integrated with patient-centered epigenetic analysis confirmed known regulators of CD38, such as RARA, while revealing XBP1 and SPI1 as other key transcription factors governing surface CD38 levels. CD38 knockdown followed by cell surface proteomics demonstrated no significant remodeling of the myeloma 'surfaceome' after genetically-induced loss of this antigen. Integrated transcriptome and surface proteome data confirmed high specificity of all-trans retinoic acid in upregulating CD38 in contrast to broader effects of azacytidine and panobinostat. Finally, unbiased phosphoproteomics identified inhibition of MAP kinase pathway signaling in tumor cells after daratumumab treatment. Our work provides a resource to design strategies to enhance efficacy of CD38-targeting immunotherapies in myeloma.

Pharmacologic Regulation of the Renin—Angiotensin System: Physiologic and Pathologic Effects

Objective: To review the physiologic and pathologic roles of the renin-angiotensin system in maintaining blood pressure, glomerular filtration rate, and myocardial tissue growth. The pharmacologic regulations of the pathologic effects of the renin-angiotensin system are emphasized, with a comparison between angiotensin-converting enzyme (ACE) inhibitors and angiotensin1 receptor (AT1) antagonists. Data Sources: English-language basic science, clinical studies, and review articles were identified using MEDLINE, IOWA, and a manual search from January 1966 through September 1999. References were also obtained from the reference section of relevant published articles. Study Selection and Data Extraction: All articles identified were evaluated for possible inclusion in this review. Evaluative and comparative data from basic science and controlled clinical studies were reviewed. Data Synthesis: The renin-angiotensin system has a plethora of physiologic and pathologic roles in the regulation of blood pressure, renal function, and cell growth. The cellular mechanisms involved in eliciting the responses to the renin-angiotensin system are discussed in detail, with an emphasis on the pharmacologic regulation of the cellular responses. The role of angiotensin II in maintaining blood pressure, glomerular filtration rate, and in regulating myocardial cell growth secondary to myocardial infarction or as a complication of congestive heart failure are all reviewed. The ACE inhibitors and AT1 antagonists have comparable pharmacologic effects that can influence their therapeutic application. The ACE inhibitors and AT, antagonists are compared regarding clinically and experimentally observed differences that may affect their therapeutic application. Conclusions: The physiologic and pathologic roles of the renin-angiotensin system make the ACE inhibitors and AT1 antagonists ideal candidates in treating many conditions. Presently, few studies have been conducted that directly compare ACE inhibitors and AT, antagonists. An understanding of the basic underlying pharmacologic principles is essential when attempting to apply the scientific and clinical information of the ACE inhibitors and AT1 antagonists with the intention of extrapolating to therapeutic utility.