Benjamin J. Capoccia

Revascularization of ischemic limbs after transplantation of human bone marrow cells with high aldehyde dehydrogenase activity

The development of cell therapies to treat peripheral vascular disease has proven difficult because of the contribution of multiple cell types that coordinate revascularization. We characterized the vascular regenerative potential of transplanted human bone marrow (BM) cells purified by high aldehyde dehydrogenase (ALDH(hi)) activity, a progenitor cell function conserved between several lineages. BM ALDH(hi) cells were enriched for myelo-erythroid progenitors that produced multipotent hematopoietic reconstitution after transplantation and contained nonhematopoietic precursors that established colonies in mesenchymal-stromal and endothelial culture conditions. The regenerative capacity of human ALDH(hi) cells was assessed by intravenous transplantation into immune-deficient mice with limb ischemia induced by femoral artery ligation/transection. Compared with recipients injected with unpurified nucleated cells containing the equivalent of 2- to 4-fold more ALDH(hi) cells, mice transplanted with purified ALDH(hi) cells showed augmented recovery of perfusion and increased blood vessel density in ischemic limbs. ALDH(hi) cells transiently recruited to ischemic regions but did not significantly integrate into ischemic tissue, suggesting that transient ALDH(hi) cell engraftment stimulated endogenous revascularization. Thus, human BM ALDH(hi) cells represent a progenitor-enriched population of several cell lineages that improves perfusion in ischemic limbs after transplantation. These clinically relevant cells may prove useful in the treatment of critical ischemia in humans.

Recruitment of the inflammatory subset of monocytes to sites of ischemia induces angiogenesis in a monocyte chemoattractant protein-1-dependent fashion

There is accumulating evidence that delivery of bone marrow cells to sites of ischemia by direct local injection or mobilization into the blood can stimulate angiogenesis. This has stimulated tremendous interest in the translational potential of angiogenic cell population(s) in the bone marrow to mediate therapeutic angiogenesis. However, the mechanisms by which these cells stimulate angiogenesis are unclear. Herein, we show that the inflammatory subset of monocytes is selectively mobilized into blood after surgical induction of hindlimb ischemia in mice and is selectively recruited to ischemic muscle. Adoptive‐transfer studies show that delivery of a small number of inflammatory monocytes early (within 48 h) of induction of ischemia results in a marked increase in the local production of MCP‐1, which in turn, is associated with a secondary, more robust wave of monocyte recruitment. Studies of mice genetically deficient in MCP‐1 or CCR2 indicate that although not required for the early recruitment of monocytes, the secondary wave of monocyte recruitment and subsequent stimulation of angiogenesis are dependent on CCR2 signaling. Collectively, these data suggest a novel role for MCP‐1 in the inflammatory, angiogenic response to ischemia.

The ubiquitin ligase Mindbomb 1 coordinates gastrointestinal secretory cell maturation

After cell fate specification, differentiating cells must amplify the specific subcellular features required for their specialized function. How cells regulate such subcellular scaling is a fundamental unanswered question. Here, we show that the E3 ubiquitin ligase Mindbomb 1 (MIB1) is required for the apical secretory apparatus established by gastric zymogenic cells as they differentiate from their progenitors. When Mib1 was deleted, death-associated protein kinase-1 (DAPK1) was rerouted to the cell base, microtubule-associated protein 1B (MAP1B) was dephosphorylated, and the apical vesicles that normally support mature secretory granules were dispersed. Consequently, secretory granules did not mature. The transcription factor MIST1 bound the first intron of Mib1 and regulated its expression. We further showed that loss of MIB1 and dismantling of the apical secretory apparatus was the earliest quantifiable aberration in zymogenic cells undergoing transition to a precancerous metaplastic state in mouse and human stomach. Our results reveal a mechanistic pathway by which cells can scale up a specific, specialized subcellular compartment to alter function during differentiation and scale it down during disease.

Antibody mediated therapy targeting CD47 inhibits tumor progression of hepatocellular carcinoma

Human hepatocellular carcinoma (HCC) has a high rate of tumor recurrence and metastasis, resulting in shortened survival times. The efficacy of current systemic therapies for HCC is limited. In this study, we used xenograft tumor models to investigate the use of antibodies that block CD47 and inhibit HCC tumor growth. Immunostaining of tumor tissue and HCC cell lines demonstrated CD47 over-expression in HCC as compared to normal hepatocytes. Macrophage phagocytosis of HCC cells was increased after treatment with CD47 antibodies (CD47mAbs) that block CD47 binding to SIRPα. Further, CD47 blockade inhibited tumor growth in both heterotopic and orthotopic models of HCC, and promoted the migration of macrophages into the tumor mass. Our results demonstrate that targeting CD47 by specific antibodies has potential immunotherapeutic efficacy in human HCC.

Autoimmune Gastritis Mediated by CD4+ T Cells Promotes the Development of Gastric Cancer

Chronic inflammation is a major risk factor for cancer, including gastric cancers and other gastrointestinal cancers. For example, chronic inflammation caused by autoimmune gastritis (AIG) is associated with an increased risk of gastric polyps, gastric carcinoid tumors, and possibly adenocarcinomas. In this study, we characterized the progression of gastric cancer in a novel mouse model of AIG. In this model, disease was caused by CD4(+) T cells expressing a transgenic T-cell receptor specific for a peptide from the H(+)/K(+) ATPase proton pump, a protein expressed by parietal cells in the stomach. AIG caused epithelial cell aberrations that mimicked most of those seen in progression of human gastric cancers, including chronic gastritis followed by oxyntic atrophy, mucous neck cell hyperplasia, spasmolytic polypeptide-expressing metaplasia, dysplasia, and ultimately gastric intraepithelial neoplasias. Our work provides the first direct evidence that AIG supports the development of gastric neoplasia and provides a useful model to study how inflammation drives gastric cancer.

Systemic levels of G‐CSF and interleukin‐6 determine the angiogenic potential of bone marrow resident monocytes

There is considerable interest in the potential of cell‐based approaches to mediate therapeutic angiogenesis for acute and chronic vascular syndromes. Using a mouse model of HLI, we showed previously that adoptive transfer of a small number of donor monocytes enhanced revascularization significantly. Herein, we provide data suggesting that the BM resident monocytes sense systemic signals that influence their future functional capacity. Specifically, following induction of distant ischemia, the angiogenic capacity of BM resident monocytes is reduced markedly. We provide evidence that G‐CSF and IL‐6 represent such “conditioning” signals. Systemic levels of G‐CSF and IL‐6 are increased significantly following induction of HLI. Accordingly, BM resident monocytes from ischemic mice exhibited increased pSTAT3 and STAT3 target gene expression. Finally, G‐CSFR−/− and IL‐6−/− mice were resistant to the deleterious effects of ischemic conditioning on monocyte angiogenic potential. RNA expression profiling suggested that ischemia‐conditioned monocytes in the BM up‐regulate the well‐described M2 polarization markers Chi3l4 and Lrg1. Consistent with this observation, M2‐skewed monocytes from SHIP−/− mice also had impaired angiogenic capacity. Collectively, these data show that G‐CSF and IL‐6 provide signals that determine the angiogenic potential of BM resident monocytes.

How form follows functional genomics: gene expression profiling gastric epithelial cells with a particular discourse on the parietal cell

The cellular composition and morphology of the stomach epithelium have been described in detail; however, the molecular mechanisms that regulate the differentiation of the various cell lineages as well as the function of mature gastric cells are far less clear. Recently, dissection of the molecular anatomy of the stomach has been boosted by the advent of functional genomics, which allows investigators to determine patterns of gene expression across virtually the entire cellular transcriptome. In this review, we discuss the impact of functional genomic studies on the understanding of gastric epithelial physiology. We show how functional genomic studies have uncovered genes that are useful as new cell lineage-specific markers of differentiation and provide new insights into cell physiology. For example, vascular endothelial growth factor B (Vegfb) has been identified as a parietal cell-specific marker that may allow parietal cells to regulate the mucosal vascular network. We also discuss how functional genomics has identified aberrantly expressed genes in disease states. Human epididymis 4 (HE4), for example, was recently identified as a metaplasia-induced gene product in mice based on microarray analysis. Finally, we will examine how analysis of higher-order patterns of gene expression can go beyond simply identifying individual genes to show how cells work as integrated systems. Specifically, we show how application of a Gene Ontology (GO) analysis of gene expression patterns from multiple tissues identifies the gastric parietal cell as an outlier, unlike other differentiated cell lineages in the stomach or elsewhere in the body.

Transcription factor MIST1 in terminal differentiation of mouse and human plasma cells

Despite their divergent developmental ancestry, plasma cells and gastric zymogenic (chief) cells share a common function: high-capacity secretion of protein. Here we show that both cell lineages share increased expression of a cassette of 269 genes, most of which regulate endoplasmic reticulum (ER) and Golgi function, and they both induce expression of the transcription factors X-box binding protein 1 (Xbp1) and Mist1 during terminal differentiation. XBP1 is known to augment plasma cell function by establishing rough ER, and MIST1 regulates secretory vesicle trafficking in zymogenic cells. We examined morphology and function of plasma cells in wild-type and Mist1(-/-) mice and found subtle differences in ER structure but no overall defect in plasma cell function, suggesting that Mist1 may function redundantly in plasma cells. We next reasoned that MIST1 might be useful as a novel and reliable marker of plasma cells. We found that MIST1 specifically labeled normal plasma cells in mouse and human tissues, and, moreover, its expression was also characteristic of plasma cell differentiation in a cohort of 12 human plasma cell neoplasms. Overall, our results show that MIST1 is enriched upon plasma cell differentiation as a part of a genetic program facilitating secretory cell function and also that MIST1 is a novel marker of normal and neoplastic plasma cells in mouse and human tissues.

CD47 blockade reduces ischemia-reperfusion injury and improves outcomes in a rat kidney transplant model.

Background Ischemia-reperfusion injury (IRI) significantly contributes to delayed graft function and inflammation, leading to graft loss. Ischemia-reperfusion injury is exacerbated by the thrombospondin-1-CD47 system through inhibition of nitric oxide signaling. We postulate that CD47 blockade and prevention of nitric oxide inhibition reduce IRI in organ transplantation. Methods We used a syngeneic rat renal transplantation model of IRI with bilaterally nephrectomized recipients to evaluate the effect of a CD47 monoclonal antibody (CD47mAb) on IRI. Donor kidneys were flushed with CD47mAb OX101 or an isotype-matched control immunoglobulin and stored at 4°C in University of Wisconsin solution for 6 hr before transplantation. Results CD47mAb perfusion of donor kidneys resulted in marked improvement in posttransplant survival, lower levels of serum creatinine, blood urea nitrogen, phosphorus and magnesium, and less histological evidence of injury. In contrast, control groups did not survive more than 5 days, had increased biochemical indicators of renal injury, and exhibited severe pathological injury with tubular atrophy and necrosis. Recipients of CD47mAb-treated kidneys showed decreased levels of plasma biomarkers of renal injury including Cystatin C, Osteopontin, Tissue Inhibitor of Metalloproteinases-1 (TIMP1), &bgr;2-Microglobulin, Vascular Endothelial Growth Factor A (VEGF-A), and clusterin compared to the control group. Furthermore, laser Doppler assessment showed higher renal blood flow in the CD47mAb-treated kidneys. Conclusion These results provide strong evidence for the use of CD47 antibody–mediated blockade to reduce IRI and improve organ preservation for renal transplantation.

Abstract 2: Phosphorylation of BNIP3 is a switch between life and death in cancer cells

Proceedings: AACR 106th Annual Meeting 2015; April 18-22, 2015; Philadelphia, PA Antibodies vs CD47 (CD47mAbs) that block the CD47-SIRPalpha interaction promote the phagocytosis of cancer cells and have efficacy in several tumor models. A select few CD47mAbs also directly kill cancer cells by lowering cellular cAMP levels leading to mitochondrial damage and cell death. These CD47mAbs are thus referred to as “dual-function” mAbs. Activation of protein kinase A prevents CD47mAb-mediated death suggesting that phosphorylation of one or more target proteins in the cancer cell can block the death mechanism. BNIP3, a member of the BH3-only family, is induced by hypoxia and oncogenes and is necessary for induction of cell death by dual-function CD47mAbs. BNIP3 can activate autophagy, a pro-survival function, and can also induce cell death by damaging mitochondria. The role of BNIP3 in cancer is controversial and context-dependent with some cancers over-expressing BNIP3 compared to low levels of expression in normal tissue, while other cancers cannot tolerate BNIP3 expression and silence the gene, often by methylation of the BNIP3 promoter. This suggests that cancers that tolerate BNIP3 expression employ an as yet unknown mechanism to protect themselves from its toxic effects. The C-terminal transmembrane (TM) domain of BNIP3 (residues 164-184) penetrates the outer mitochondrial membrane allowing the extreme C-terminal ten residue tail of BNIP3 (RRLTTSTSTF, residues 185-194) to extend across the intermembrane space to bind OPA1 on the inner mitochondrial membrane, a key step in the death mechanism. We used a phosphosite-specific antibody to detect phosphorylation of BNIP3 immunoprecipitated from Jurkat leukemia cells at residue T188 which resides in a canonical protein kinase A site (RRLT, amino acids 185-188). Using mass spectrometry of 6His-tagged BNIP3 isolated from HEK293 cells treated with 8BrcAMP, we identified as many as 4 additional phosphorylated sites in the C-terminal tail sequence (residues 189-194, TSTSTF). We generated phosphomimetic (S/T to D) and unphosphorylated (S/T to A or N) mutations at these residues and expressed the mutant BNIP3 proteins in 293 cells. All of the BNIP3 mutants associated with mitochondria but only the phosphomimetic mutants prevented BNIP3-induced mitochondrial damage and cell death. In contrast, mutation of the phosphorylated S/T residues to unphosphorylated residues resulted in rapid and extensive cell death. Importantly, phosphomimetic C-terminal BNIP3 residues blocked cell death without preventing autophagy, providing evidence that the two roles of BNIP3 can be regulated independently. We replicated these results in one lung cancer and three breast cancer cell lines. These findings suggest that phosphorylation at the C-terminus of BNIP3 is a switch that determines the pro-survival vs pro-death effects of BNIP3. Dual-function CD47mAbs may act by dephosphorylating BNIP3 expressed in tumor cells thus unleashing its killing potential. Citation Format: William Frazier, Katherine Liu, Julie Dimitry, Benjamin Capoccia, Pamela Manning, Robert Karr. Phosphorylation of BNIP3 is a switch between life and death in cancer cells. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 2. doi:10.1158/1538-7445.AM2015-2