The Dual Role of Platelets in the Cardiovascular Risk of Chronic Inflammation

Patients with chronic inflammatory diseases often exhibit cardiovascular risk. This risk is associated with the systemic inflammation that persists in these patients, causing a sustained endothelial activation. Different mechanisms have been considered responsible for this systemic inflammation, among which activated platelets have been regarded as a major player. However, in recent years, the role of platelets has become controversial. Not only can this subcellular component release pro- and anti-inflammatory mediators, but it can also bind to different subsets of circulating lymphocytes, monocytes and neutrophils modulating their function in either direction. How platelets exert this dual role is not yet fully understood.

Identification of the chromosome localization domain of the Drosophila nod kinesin-like protein.

The nod kinesin-like protein is localized along the arms of meiotic chromosomes and is required to maintain the position of achiasmate chromosomes on the developing meiotic spindle. Here we show that the localization of ectopically expressed nod protein on mitotic chromosomes precisely parallels that observed for wild-type nod protein on meiotic chromosomes. Moreover, the carboxyl-terminal half of the nod protein also binds to chromosomes when overexpressed in mitotic cells, whereas the overexpressed amino-terminal motor domain binds only to microtubules. Chromosome localization of the carboxyl-terminal domain of nod depends upon an 82-amino acid region comprised of three copies of a sequence homologous to the DNA-binding domain of HMG 14/17 proteins. These data map the two primary functional domains of the nod protein in vivo and provide a molecular explanation for the directing of the nod protein to a specific subcellular component, the chromosome.

Immunogold electron microscopy of phytochrome in Avena: identification of intracellular sites responsible for phytochrome sequestering and enhanced pelletability.

Using monoclonal antibodies to the plant photoreceptor, phytochrome, we have investigated by immunogold electron microscopy the rapid, red light-induced, intracellular redistribution (termed "sequestering") of phytochrome in dark-grown Avena coleoptiles. Pre-embedding immunolabeling of 5-micron-thick cryosections reveals that sequestered phytochrome is associated with numerous, discrete structures of similar morphology. Specific labeling of these structures was also achieved by post-embedding ("on-grid") immunostaining of LR-White-embedded tissue, regardless of whether the tissue had been fixed chemically or by freeze substitution. The phytochrome-associated structures are globular to oval in shape, 200-400 nm in size, and are composed of amorphous, granular material. No morphologically identifiable membranes are present either surrounding or within these structures, which are often present as apparent aggregates that approach several micrometers in size. An immunogold labeling procedure has also been developed to identify the particulate, subcellular component with which phytochrome is associated in vitro as a consequence of irradiation of Avena coleoptiles before their homogenization. Structures with appearance similar to those identified in situ are the only components of the pelletable material that are specifically labeled with gold. We conclude that the association of phytochrome with these structures in Avena represents the underlying molecular event that ultimately is expressed both as red light-induced sequestering in vivo and enhanced pelletability of phytochrome detected in vitro.