The HDAC inhibitors trichostatin A and suberoylanilide hydroxamic acid exhibit multiple modalities of benefit for the vascular pathobiology of sickle transgenic mice.

The vascular pathobiology of sickle cell anemia involves inflammation, coagulation, vascular stasis, reperfusion injury, iron-based oxidative biochemistry, deficient nitric oxide (NO) bioavailability, and red cell sickling. These disparate pathobiologies intersect and overlap, so it is probable that multimodality therapy will be necessary for this disease. We have, therefore, tested a histone deacetylase (HDAC) inhibitor, trichostatin A (TSA), for efficacy in reducing endothelial activation. We found that pulmonary vascular endothelial VCAM-1 and tissue factor (TF) expression (both are indicators of endothelial activation) are powerfully and significantly inhibited by TSA. This is seen both with pretreatment before the inducing stress of hypoxia/reoxygenation (NY1DD sickle transgenic mouse), and upon longer-term therapy after endothelial activation has already occurred (hBERK1 sickle mouse at ambient air). In addition, TSA prevented vascular stasis in sickle mice, it exhibited activity as an iron chelator, and it induced expression of the antisickling hemoglobin, hemoglobin F. Notably, the TSA analog SAHA (suberoylanilide hydroxaminc acid) that is already approved for human clinical use exhibits the same spectrum of biologic effects as TSA. We suggest that SAHA possibly could provide true, multimodality, salubrious effects for prevention and treatment of the chronic vasculopathy of sickle cell anemia.

Endothelial nitric oxide synthase and nitric oxide regulate endothelial tissue factor expression in vivo in the sickle transgenic mouse.

Activation of the coagulation system is a characteristic feature of sickle cell anemia, which also includes clinical thrombosis. The sickle transgenic mouse abnormally expresses tissue factor (TF) on the pulmonary vein endothelium. Knowing that this aberrancy is stimulated by inflammation, we sought to determine whether nitric oxide (NO) contributes to regulation of endothelial TF expression in the sickle mouse model. We used the NY1DD sickle mouse, which exhibits a low-TF to high-TF phenotype switch on exposure to hypoxia/reoxygenation. Manipulations of NO biology, such as breathing NO or addition of arginine or L-NAME (N-nitro-L-arginine-methyl-ester) to the diet, caused significant modulations of TF expression. This was also seen in hBERK1 sickle mice, which have a different genetic background and already have high-TF even at ambient air. Study of NY1DD animals bred to overexpress endothelial nitric oxide synthase (eNOS; eNOS-Tg) or to have an eNOS knockout state (one eNOS(-/-) animal and several eNOS(+/-) animals) demonstrated that eNOS modulates endothelial TF expression in vivo by down-regulating it. Thus, the biodeficiency of NO characteristic of patients with sickle cell anemia may heighten risk for activation of the coagulation system.

Cellular levels of aldehyde dehydrogenases (ALDH1A1 and ALDH3A1) as predictors of therapeutic responses to cyclophosphamide-based chemotherapy of breast cancer: a retrospective study. Rational individualization of oxazaphosphorine-based cancer chemotherapeutic regimens.

PURPOSE: In preclinical models, established molecular determinants of cellular sensitivity to cyclophosphamide, long a mainstay of chemotherapeutic regimens used to treat breast cancers, include the aldehyde dehydrogenases that catalyze the detoxification of this agent, namely, ALDH1A1 and ALDH3A1. As judged by bulk quantification of relevant catalytic activities, as well as of relevant proteins (ELISAs), tissue levels of these enzymes vary widely in primary and metastatic breast malignancies. Thus, interindividual variation in the activity of either of these enzymes in breast cancers could contribute to the wide variation in clinical responses obtained when such regimens are used to treat these malignancies. Direct evidence for this notion was sought in the present investigation. METHODS: Cellular levels of ALDH1A1 and ALDH3A1 in 171 repository human breast tumor (122 primary and 49 metastatic) samples were semiquantified using immunocytochemical staining. Clinical responses were retrieved from the archived medical records of each of 48 metastatic breast cancer sample donors, 26 of whom had been treated with a cyclophosphamide-based chemotherapeutic regimen subsequent to tumor sampling and 22 of whom had not. The premise that cellular levels of ALDH1A1 and/or ALDH3A1 predict clinical responses to cyclophosphamide-based chemotherapeutic regimens was submitted to statistical analysis. RESULTS: Confirming an earlier report, ALDH1A1 and ALDH3A1 levels varied widely in both primary and metastatic breast tumor cells. When measurably present, each of the enzymes appeared to be evenly distributed throughout a given tumor cell population. Retrospective analysis indicated that cellular levels of ALDH1A1, but not those of ALDH3A1, were (1) significantly higher in metastatic tumor cells that had survived exposure to cyclophosphamide than in those that had not been exposed to this drug, and (2) significantly higher in metastatic tumors that did not respond (tumor size did not decrease or even increased) to subsequent treatment with cyclophosphamide-based chemotherapeutic regimens than in those that did respond (tumor size decreased) to such regimens. The therapeutic outcome of cyclophosphamide-based chemotherapy corresponded to cellular ALDH1A1 levels in 77% of cases. The frequencies of false-positives (cyclophosphamide-based chemotherapy not effective when a low level of ALDH1A1 predicted it would be) and false-negatives (cyclophosphamide-based chemotherapy effective when a high level of ALDH1A1 predicted it would not be) were 0.00 and 0.43, respectively. Thus, partial or complete responses to cyclophosphamide-based chemotherapy occurred 2.3 times more often when the ALDH1A1 level was low than when it was high. CONCLUSIONS: Given (1) the wide range of ALDH1A1 levels observed in malignant breast tissues, (2) that ALDH1A1 levels in primary breast tumor tissue, as well as those in normal breast tissue, directly reflect ALDH1A1 levels in metastatic breast tumor cells derived therefrom, and (3) the findings reported here, measurement of ALDH1A1 levels in primary breast malignancies and/or normal breast tissue prior to the initiation of chemotherapy is likely to be of value in predicting the therapeutic potential, or lack of potential, of cyclophosphamide and other oxazaphosphorines, e.g. ifosfamide, in the treatment of primary, as well as metastatic, breast cancer, thus providing a rational basis for the design of individualized therapeutic regimens for this disease. Failure to observe the expected inverse relationship between clinical responses to cyclophosphamide-based chemotherapeutic regimens and ALDH3A1 levels was probably because even the highest breast tumor tissue ALDH3A1 level thus far reported appears to be below the threshold level at which ALDH3A1-catalyzed detoxification of oxazaphosphorines becomes pharmacologically meaningful. However, ALDH3A1 levels in certain other malignancies, e.g. those of the alimentary tract and lung, may be of a sufficient magnitude in that regard.

Nuclear factor-kappa B (NFkappaB) component p50 in blood mononuclear cells regulates endothelial tissue factor expression in sickle transgenic mice: implications for the coagulopathy of sickle cell disease.

Sickle cell anemia is accompanied by the activation of coagulation and thrombosis. We have studied the abnormal expression of tissue factor (TF) by the pulmonary vein endothelium of the mild-phenotype NY1DD sickle transgenic. As detected by immunofluorescence microscopy, this occurs only after the NY1DD mouse is exposed to hypoxia/reoxygenation (H/R), which actually causes ischemia/reperfusion in the sickle cell disease-but not the normal-mouse model. We tested the hypothesis that the nuclear factor-kappa B (NFkappaB)-activating inflammation that develops in post-H/R NY1DD mice is responsible for this phenotype switch. Various NFkappaB inhibitors (including p50-specific andrographolide) demonstrated that endothelial TF positivity is NFkappaB dependent. Several systemic inflammatory stimulators (tumor necrosis factor [TNFalpha], lipopolysaccharide, thioglycollate, and carageenan) given to control mice showed that the inflammatory promotion of TF expression by only pulmonary vein endothelium is not specific to the sickle cell disease model. We bred the NFkappaB(p50)-/- state into the NY1DD mouse. Combined with marrow transplantation, this allowed the creation of NY1DD mice that were NFkappaB(p50)-/- only in peripheral blood cells (and marrow) versus only in vessel walls (and tissues). This process revealed that endothelial TF expression in the NY1DD mouse is highly dependent on NFkappaB(p50) in peripheral blood mononuclear cells-but not in the vessel wall. In confirmation, the infusion of post-H/R sickle mouse blood mononuclear cells into naïve NY1DD mice stimulated endothelial TF expression; the infusion of such cells from unstimulated sickle cell disease mice at ambient air did not stimulate TF expression. We conclude that peripheral blood mononuclear cells indirectly promote endothelial TF expression via a NFkappaB(p50)-dependent mechanism. This approach may be relevant to the role of coagulopathy in clinical sickle cell disease.

Robust vascular protective effect of hydroxamic acid derivatives in a sickle mouse model of inflammation.

OBJECTIVE: Clinically, the vascular pathobiology of human sickle cell disease includes an abnormal state of chronic inflammation and activation of the coagulation system. Since these biologies likely underlie development of vascular disease in sickle subjects, they offer attractive targets for novel therapeutics. Similar findings characterize the sickle transgenic mouse, which therefore provides a clinically relevant inflammation model. METHOD: The authors tested two polyhydroxyphenyl hydroxamic acid derivatives, didox and trimidox, in sickle transgenic mice. Animals were examined by intravital microscopy (cremaster muscle and dorsal skin fold preparations) and by histochemistry before and after transient exposure to hypoxia, with versus without preadministration of study drug. Previous studies have validated the application of hypoxia/reoxygenation to sickle transgenic mice as a disease-relevant model. RESULTS: Animals pretreated with these agents exhibited marked improvements in leukocyte/ endothelial interaction, hemodynamics and vascular stasis, and endothelial tissue factor expression. Thus, these drugs unexpectedly exert powerful inhibition on both the inflammation and coagulation systems. CONCLUSIONS: Each of these changes is expected to be therapeutically beneficial in systemic inflammatory disease in general, and in sickle disease in particular. Thus, these novel compounds offer the advantage of having multiple therapeutic benefits in a single agent.

Endothelial cell expression of tissue factor in sickle mice is augmented by hypoxia/reoxygenation and inhibited by lovastatin.

Abnormal tissue factor (TF) expression has been demonstrated on blood monocytes and circulating endothelial cells in humans with sickle cell anemia. We have now studied sickle transgenic mice to help define the biology of endothelial TF expression in sickle disease. Using immunostaining of tissue sections, we find that this is confined almost exclusively to the pulmonary veins. About 15% and 13% of these exhibit TF-positive endothelium in the wild-type normal mouse and the normal human hemoglobin (HbA)-expressing control transgenic mouse, respectively. The mild sickle mouse is indistinguishable from normal (approximately 14% positive), but TF expression is significantly elevated in the moderate and severe mouse models of sickle disease (approximately 29% and approximately 41% positive, respectively). Exposure of the mild sickle mouse to hypoxia for 3 hours, followed by reoxygenation, converted its TF expression phenotype to that of the severe sickle mouse (approximately 36% positive). Pretreatment with lovastatin eliminated excessive expression of TF in the posthypoxic mild sickle mouse (approximately 16% positive) and in the more severe mouse at ambient air (approximately 21% positive). In addition to identifying tissue expression of endothelial TF in the sickle lung, these studies implicate reperfusion injury physiology in its expression and suggest a rationale for use of statins in sickle disease.