Peter D. Winocour scite author profile

Although platelets can contribute to atherosclerosis and its thromboembolic complications in the nondiabetic population, the role of platelets in enhanced vascular disease in the diabetic population remains unclear. Most studies indicate that platelet function in vitro is enhanced in platelets from people and animals with diabetes, and the mechanisms are being identified. There remains some controversy about whether platelet changes occur before, and therefore could contribute to, vascular complications or whether they are secondary to vascular disease. It is possible that only intervention trials to determine if inhibiting platelet function limits the progression of vascular disease in diabetic patients will definitively answer this question. The earlier premise that enhanced activity of the arachidonate pathway is responsible for the hypersensitivity of platelets from diabetic humans needs to be modified to recognize that additional mechanisms are involved in platelet activation and are modified in people with diabetes and also that altered activity of the arachidonate pathway may reflect changes in earlier pathways involved in platelet activation. Clearly, alterations in these nonarachidonate pathways need to be taken into account when considering the appropriate antiplatelet agents to use in intervention trials. Information about whether hypersensitivity of platelets from people with diabetes persists in vivo and, if so, how this influences platelet-vessel wall interactions and thrombotic tendencies needs to be pursued more intensely in suitable animal models so that the theories developed from studies in vitro can be tested in the more complex environment in vivo. These are important areas for research in the future.

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Decreased Platelet Membrane Fluidity Due to Glycation or Acetylation of Membrane Proteins

Winocour

Watała

Perry

et al. 1992

Thromb Haemost

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SummaryPlatelets from diabetic subjects and animals are hypersensitive to agonists in vitro. Membrane fluidity modulates cell function and previously we observed reduced membrane fluidity in platelets from diabetic patients associated with hypersensitivity to thrombin. We previously reported that decreased fluidity of isolated platelet membranes from diabetic patients is associated with increased glycation of platelet membrane proteins, but not with any change in the cholesterol to phospholipid molar ratio. We have now examined in vitro whether incubation of platelet membranes in a high glucose medium causes sufficient glycation to reduce membrane fluidity. Incubation of platelet membranes from control subjects in a high glucose (16.1 mM) medium for 10 days at 37° C led to an increase in the extent of glycation of membrane proteins and a decrease in membrane fluidity (indicated by an increase in steady state fluorescence polarization); most of the changes occurred within the first 3 days of incubation. Incubation of platelet membranes with 5.4 mM glucose had less effect. In contrast, incubation of platelet membranes with the same concentrations of 1–0-methylglucose did not cause a change in either the extent of glycation of proteins or membrane fluidity. We also determined if acetylation by aspirin or acetyl chloride of the sites available for glycation on platelet membrane proteins leads to a similar reduction in membrane fluidity. Pretreatment of platelet membranes with aspirin or acetyl chloride diminished the extent of glycation that occurred when platelet membranes were subsequently incubated with glucose, but membrane fluidity was reduced even in the absence of glucose; subsequent incubation with glucose caused no further reduction in membrane fluidity. Similar results were obtained when red blood cells were incubated with high concentrations of glucose or methyl glucose either with or without pretreatment with aspirin or acetyl chloride. Further experiments using platelet membranes showed that the reduction in membrane fluidity due to aspirin was independent of its acetylating effect on platelet cyclo-oxygenase. Ingestion of aspirin also caused a reduction in membrane fluidity of platelets. Therefore, glycation of platelet membrane proteins reduces membrane fluidity, but the effect results from occupation of the sites available for glycation and not the presence of glucose moieties per se at these sites. Acetylation of platelet membrane proteins either in vitro or in vivo also reduces membrane fluidity; this effect is not associated with platelet hypersensitivity to thrombin.

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New concepts about the pathogenesis of atherosclerosis in diabetes mellitus

Colwell¹,

Winocour²,

Lopes‐Virella³

et al. 1983

The American Journal of Medicine

153

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Application of XIAP Antisense to Cancer and Other Proliferative Disorders: Development of AEG35156/ GEM®640

LaCasse

Kandimalla

Winocour

et al. 2005

Annals of the New York Academy of Sciences

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Targeting apoptosis control provides a novel therapeutic approach to the treatment of cancer and other proliferative disorders. We summarize the evidence for apoptosis deregulation in cancer and describe the pivotal role of XIAP, the X-linked Inhibitor-of-APoptosis. XIAP is the predominant inhibitor of caspases 3, 7 and 9 in cells, which suppresses the programmed cell death effector capability of these proteases. Evidence is presented validating XIAP as a cancer target. The inhibition or downregulation of XIAP in cancer cells lowers the apoptotic threshold, thereby inducing cell death and/or enhancing the cytotoxic action of chemotherapeutic agents. We describe the development of AEG35156 (also named GEM640), a second generation antisense compound targeting XIAP, from concept to in vivo preclinical proof-of-principle studies, through formal toxicology, and to a phase 1 clinical trial in cancer patients.

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Do Platelets Have Anything To Do With Diabetic Microvascular Disease?

1983

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It has been postulated that abnormal platelet and endothelial function may contribute to microangiopathy in diabetes mellitus. If this proposal is correct, alterations in platelet and endothelial function should be found before the appearance of vascular disease in insulin-dependent patients and in animal models of diabetes mellitus. This appears to be the case for the following: platelet aggregation, increased platelet production of the proaggregatory prostaglandin metabolite thromboxane, decreased endothelial production of the antiaggregatory prostaglandin prostacyclin, and decreased platelet survival. Insulin therapy will return some of these findings to normal. Platelet-plasma interactions that promote platelet aggregation and increased plasma levels of the platelet-specific protein beta-thromboglobulin have been reported in insulin-dependent diabetic patients who have not manifested vascular complications as well as in those with vascular complications. It has now been demonstrated in animal models that platelet microthrombi are found in small retinal vessels after months of experimental diabetes. Collectively, these findings demonstrate that alterations in platelet and endothelial function that favor thrombosis occur early in the diabetic state and may contribute to microvascular disease. There are several ongoing studies of antiplatelet agents in diabetic vascular disease that will provide clinical evidence bearing on the major postulate. Until these and other studies are completed, the platelet-endothelial story remains an attractive hypothesis in the genesis of diabetic microvascular disease.

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Peter D. Winocour

Platelet Abnormalities in Diabetes Mellitus

Decreased Platelet Membrane Fluidity Due to Glycation or Acetylation of Membrane Proteins

New concepts about the pathogenesis of atherosclerosis in diabetes mellitus

Application of XIAP Antisense to Cancer and Other Proliferative Disorders: Development of AEG35156/ GEM®640

Do Platelets Have Anything To Do With Diabetic Microvascular Disease?

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