PET and SPECT imaging of apoptosis in vulnerable atherosclerotic plaques with radiolabeled Annexin A5.

Atherosclerosis still represents killer number one in industrialized nations, and is starting to have increased impact in developing countries. Atherosclerotic plaques are the net result of a complex interplay between vascular cholesterol deposition, inflammatory activity and extracellular matrix formation. The result is luminal narrowing of arteries, which may ultimately lead to compromised blood flow to essential body organs, most notoriously to the heart. Most of the cardiovascular events that are caused by atherosclerosis, such as acute myocardial infarction or stroke, are the result of a transition of so-called stable atherosclerotic plaques to vulnerable plaques, that are prone to rupture. The direct consequence of atherosclerotic plaque rupture is exposure of thrombogenic plaque constituents to the blood, leading to instant local thrombus formation. The formation of this localized thrombus may ultimately result in sudden obstruction of blood flow and consequent infarction of distal tissue. Clinical risk profiling methods, such as the Framingham and Procam risk scores, are reasonable predictors of myocardial infarction over a 10-year time-span. However, the challenge remains to identify those patients with a very high risk of suffering from myocardial infarction in the coming months. Imaging may provide the necessary diagnostic information to identify such individuals. The transition of stable atherosclerotic plaques to vulnerable plaques is typically heralded by inflammation, thinning of the overlying fibrous cap, and the presence of a large necrotic core. Apoptosis is linked to all of these features of plaque vulnerability, and may, therefore, provide uniquely useful targets for the identification of plaque vulnerability. In recent years, a number of molecular imaging technologies have been developed to image apoptosis, which will be discussed in this review. Further development of apoptosis imaging technologies may aid us in the years to come in the quest to identify patients with critical cardiovascular risks, to treat myocardial infarction in its imminent, instead of its evident phase.

Effects of moderate alcohol consumption on folate and vitamin B(12) status in postmenopausal women.

BACKGROUND: Although alcohol intake has been positively associated with breast cancer risk in epidemiologic studies, a causal relationship has not been established, and the mechanisms mediating this association are speculative. Alcohol may act through altered status of folate and vitamin B(12), two vitamins required for DNA methylation and nucleotide synthesis, and thus cell integrity. Although the effects of heavy alcohol intake on folate and vitamin B(12) status have been well-documented, few studies have addressed the effects of moderate alcohol intake in a controlled setting. OBJECTIVE: The objective of this study was to determine the effects of moderate alcohol intake on folate and vitamin B(12) status in healthy, well-nourished, postmenopausal women. DESIGN: The study design was a randomized, diet-controlled crossover intervention. Postmenopausal women (n=53) received three 8-week alcohol treatments in random order: 0, 15, and 30 g/day. Treatment periods were preceded by 2-5-week washout periods. Blood collected at baseline and week 8 of each treatment period was analyzed for serum folate, vitamin B(12), homocysteine (HCY), and methylmalonic acid (MMA) concentrations. RESULTS: After adjusting for body mass index (BMI), a significant 5% decrease was observed in mean serum vitamin B(12) concentrations from 0 to 30 g of alcohol/day (461.45+/-30.26 vs 440.25+/-30.24 pg/ml; P=0.03). Mean serum HCY concentrations tended to increase by 3% from 0 to 30 g of alcohol/day (9.44+/-0.37 vs 9.73+/-0.37 micromol/l; P=0.05). Alcohol intake had no significant effects on serum folate or MMA concentrations. CONCLUSIONS: Among healthy, well-nourished, postmenopausal women, moderate alcohol intake may diminish vitamin B(12) status.

Domains of human c-myc protein required for autosuppression and cooperation with ras oncogenes are overlapping.

Amino acids 106 to 143 and 354 to 433 of the human c-myc protein (439 amino acids) were shown to be required for the protein to suppress c-myc gene transcription and were found to exactly overlap with those necessary for c-myc to cooperate with ras oncogenes in the transformation of rat embryo fibroblasts. The essential carboxyl-terminal region harbors structural motifs (a basic region, a helix-loop-helix motif, and a "leucine zipper"), which, in other proteins, can mediate dimerization and sequence-specific DNA binding.

Negative autoregulation of c-myc transcription.

The introduction of activated c-myc and v-myc genes into a variety of non-established and established cells results in the suppression of endogenous c-myc expression. As measured in Rat-1 fibroblasts, the suppression occurs at the level of transcriptional initiation. Moreover, the extent of the down-regulation is proportional to the cellular concentration of c-myc protein, and the critical concentration range in which the endogenous c-myc RNA is effectively suppressed corresponds to that found in non-transformed cells. In addition, the autoregulatory mechanism is not only dependent on c-myc protein, but also requires additional trans-acting factors. These results support a role for c-myc in the regulation of cellular gene transcription and suggest that a negative feedback mechanism can act as a homeostatic regulator of c-myc expression in vivo.

C-MYC: evidence for multiple regulatory functions.

The nuclear c-myc proto-oncogene promotes cell proliferation and can inhibit terminal differentiation as well as induce immortalisation in its oncogenic form. There is increasing evidence that c-myc exerts these biological activities by modulating transcription and by directly affecting the initiation of DNA replication. The regulation of these disparate activities may involve the carboxyl end of the c-myc protein, which is essential for transformation and autosuppression of c-myc transcription. Conserved motifs in this region of the c-myc protein may mediate complex formation and sequence-specific nucleic acid binding.