Leukemia stem cells (LSCs) are thought to play a central role in the pathogenesis of acute leukemia and likely contribute to both disease initiation and relapse. Therefore, identification of agents that target LSCs is an important consideration for the development of new therapies. To this end, we have previously demonstrated that the naturally occurring compound parthenolide (PTL) can induce death of human LSCs in vitro while sparing normal hematopoietic cells. However, PTL has relatively poor pharmacologic properties that limit its potential clinical use.Consequently, we generated a family of PTL analogs designed to improve solubility and bioavailability. These studies identified an analog, dimethylaminoparthenolide (DMAPT), which induces rapid death of primary human LSCs from both myeloid and lymphoid leukemias, and is also highly cytotoxic to bulk leukemic cell populations. Molecular studies indicate the prevalent activities of DMAPT include induction of oxidative stress responses, inhibition of NF-B, and activation of p53. The compound has approximately 70% oral bioavailability, and pharmacologic studies using both mouse xenograft models and spontaneous acute canine leukemias demonstrate in vivo bioactivity as determined by functional assays and multiple biomarkers. Therefore, based on the collective preclinical data, we propose that the novel compound DMAPT has the potential to target human LSCs in vivo. IntroductionRecent studies have demonstrated that myeloid leukemia and certain forms of lymphoid leukemia arise from malignant stem cells (called leukemia stem cells [LSCs]). [1][2][3] LSCs are typically found in a quiescent state and are thus unlikely to respond to standard chemotherapeutic agents that preferentially eradicate actively cycling cells. [4][5][6][7] Indeed, the persistence of LSCs following chemotherapy may be a major factor contributing to clinical relapse. 8,9 In addition, conventional leukemia therapy is also substantially toxic to normal hematopoietic cells and frequently results in severe myelosuppression. Therefore, given the drugrefractory nature of LSCs, and the importance of normal hematopoiesis, identification of less toxic and more specific forms of therapy are important priorities for the development of better therapeutic regimens.As a foundation for developing more selective leukemia treatments, our previous experiments have investigated basic properties of primitive acute myelogenous leukemia (AML) cells. These studies showed that LSCs from different AML subtypes share characteristics 10 that are unique to AML and thus represent potential therapeutic targets for the selective ablation of LSCs relative to their normal counterparts. 11,12 Specifically, we reported that NF-B, a known regulator of growth and survival, is constitutively active in LSCs but not in normal hematopoietic stem cells (HSCs). 13 Notably, many traditional cancer therapies induce activation of NF-B, a potentially undesirable characteristic likely to facilitate survival of malignant cells. 14,15 Given the abi...
The purpose of this study was to provide an initial assessment of the potential biologic activity of toceranib phosphate (Palladia®) in select solid tumors in dogs. Cases in which toceranib was used to treat dogs with anal sac anal gland adenocarcinoma, metastatic osteosarcoma, thyroid carcinoma, head and neck carcinoma, and nasal carcinoma were included. Clinical benefit (CB) was observed in 63/85 (74%) dogs including 28/32 anal sac tumors (8PR, 20SD), 11/23 osteosarcomas (1PR, 10SD), 12/15 thyroid carcinomas (4PR, 8SD), 7/8 head and neck carcinomas (1CR, 5PR, 1SD) and 5/7 (1CR, 4SD) nasal carcinomas. For dogs experiencing CB, the median dose of toceranib was 2.8 mg/kg, 36/63 (58.7%) were dosed on a Monday/Wednesday/Friday basis, and 47/63 (74.6%) were treated 4 months or longer. While these data povide preliminary evidence that toceranib exhibits CB in dogs with certain solid tumors, future prospective studies are necessary to define its true activity.
Abstract-A hallmark of atherosclerotic cardiovascular disease (CVD) is the accumulation of cholesterol in arterial macrophages. Factors that modulate circulating and tissue cholesterol levels have major impacts on initiation, progression, and regression of CVD. Four members of the ATP-binding cassette (ABC) transporter family play important roles in this modulation. ABCA1 and ABCG1 export excess cellular cholesterol into the HDL pathway and reduce cholesterol accumulation in macrophages. ABCG5 and ABCG8 form heterodimers that limit absorption of dietary sterols in the intestine and promote cholesterol elimination from the body through hepatobiliary secretion. All 4 transporters are induced by the same sterol-sensing nuclear receptor system. ABCA1 expression and activity are also highly regulated posttranscriptionally by diverse processes. ABCA1 mutations can cause a severe HDL-deficiency syndrome characterized by cholesterol deposition in tissue macrophages and prevalent atherosclerosis. ABCG5 or ABCG8 mutations can cause sitosterolemia, in which patients accumulate cholesterol and plant sterols in the circulation and develop premature CVD. Disrupting Abca1 or Abcg1 in mice promotes accumulation of excess cholesterol in macrophages, and manipulating mouse macrophage ABCA1 expression affects atherogenesis. Overexpressing ABCG5 and ABCG8 in mice attenuates diet-induced atherosclerosis in association with reduced circulating and liver cholesterol.
The anti-CD20 mAb rituximab is central to the treatment of B-cell malignancies, but resistance remains a significant problem. We recently reported that resistance could be explained, in part, by internalization of rituximab (type I anti-CD20) from the surface of certain B-cell malignancies, thus limiting engagement of natural effectors and increasing mAb consumption. Internalization of rituximab was most evident in chronic lymphocytic leukemia (CLL) and mantle cell lymphoma (MCL), but the extent of internalization was heteroge- IntroductionThe anti-CD20 mAb rituximab has improved the overall survival of patients with follicular (FL) and diffuse large B-cell lymphoma (DLBCL). [1][2][3][4] However, in MCL, only modest responses are seen 5 and in CLL, fludarabine, cyclophosphamide and rituximab (FCR) therapy delivers improved responses but has yet to show a similar improvement in overall survival, 6 albeit the current follow-up is relatively short. Interestingly, those responses seen in CLL have often been achieved with high doses of rituximab, 6 suggesting that more mAb is needed to coat the targets or that it is consumed in some way. Even within rituximab-responsive lymphomas, a proportion of cases show resistance on first treatment with rituximab or eventually become resistant to rituximab-containing combination therapy (reviewed in Stolz et al 7 ). The molecular basis of this resistance and the observed sensitivity of different lymphoma subtypes is unclear (reviewed in Lim et al 8 ), but is highly relevant to improving outcomes.In addition to understanding target resistance, many groups are working to deliver anti-CD20 mAb reagents with improved affinity and more potent engagement of cytotoxic effectors. Anti-CD20 mAb can be defined as type I (eg, rituximab, ofatumumab) or type II (eg tositumumab, GA101), according to their ability to redistribute CD20 into lipid rafts in the plasma membrane and function in various effector assays. 9-11 It is still not clear what characteristics are required for the optimal reagent, but it is generally accepted that Fc:Fc ␥ receptor (Fc␥R) interactions are crucial to the efficacy of anti-CD20 mAb. [12][13][14][15] In particular, Fc␥RIIIa on myeloid effectors appears critical in controlling Ab potency and in keeping with this, lymphoma patients bearing the higher affinity 158V allele in Fc␥RIIIa respond better to rituximab compared with those with the low affinity 158F allotype, 16 leading many investigators to focus on augmenting the interaction of mAb with Fc␥RIIIa, for example via defucosylation. 17 Less attention has been given to the potential effects of the ITIM-containing inhibitory Fc␥R, Fc␥RIIb. Fc␥RIIb is a negative regulator of ITAM-containing receptors, such as the B-cell receptor (BCR) and the activatory Fc␥R. 18 Most hematopoietic cells coexpress inhibitory and activatory Fc␥R, and tumors are reported to be more sensitive to mAb immunotherapy in Fc␥RII Ϫ/Ϫ mice because of the removal of the inhibitory restraint of this receptor from myeloid effectors such as macro...
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