Platelet tissue factor comes of age

Cerebral malaria: insights from host-parasite protein-protein interactions

Background

Cerebral malaria is a form of human malaria wherein Plasmodium falciparum-infected red blood cells adhere to the blood capillaries in the brain, potentially leading to coma and death. Interactions between parasite and host proteins are important in understanding the pathogenesis of this deadly form of malaria. It is, therefore, necessary to study available protein-protein interactions to identify lesser known interactions that could throw light on key events of cerebral malaria.

Methods

Sequestration, haemostasis dysfunction, systemic inflammation and neuronal damage are key processes of cerebral malaria. Key events were identified from literature as being crucial to these processes. An integrated interactome was created using available experimental and predicted datasets as well as from literature. Interactions from this interactome were filtered based on Gene Ontology and tissue-specific annotations, and further analysed for relevance to the key events.

Results

PfEMP1 presentation, platelet activation and astrocyte dysfunction were identified as the key events influencing the disease. 48896 host-parasite along with other host-parasite, host-host and parasite-parasite protein-protein interactions obtained from a disease-specific corpus were combined to form an integrated interactome. Filtering of the interactome resulted in five host-parasite PPI, six parasite-parasite and two host-host PPI. The analysis of these interactions revealed the potential significance of apolipoproteins and temperature/Hsp expression on efficient PfEMP1 presentation; role of MSP-1 in platelet activation; effect of parasite proteins in TGF-β regulation and the role of albumin in astrocyte dysfunction.

Conclusions

This work links key host-parasite, parasite-parasite and host-host protein-protein interactions to key processes of cerebral malaria and generates hypotheses for disease pathogenesis based on a filtered interaction dataset. These hypotheses provide novel and significant insights to cerebral malaria.

"Message in the platelet"--more than just vestigial mRNA!

Although mammalian platelets are anucleated cells, a number of studies have shown that they retain a pool of messenger RNA (mRNA) carried over from the megakaryocyte during thrombopoiesis. Platelet mRNA was originally thought to be relatively unstable and short-lived within the youngest cells and has been used as a potential marker of platelet turnover. In this article we will discuss both theoretical and methodological issues related to the measurement of these younger, "reticulated platelets". A key question relating to platelet mRNA is also whether it has any functional relevance other than a marker of platelet immaturity. Evidence going back more than 30 years suggests that platelets can biosynthesize proteins. However, it is only very recently that the nature and specificity of platelet mRNA has been examined in any detail. Difficulties in obtaining pure platelet mRNA, free of contamination from other cells has added to the complexity of unravelling this story. However, there is now clear evidence that platelets contain small but significant levels of message for a variety of proteins. The platelet mRNA pool is much richer and more diverse than previously thought and recent data suggests that regulated synthesis of a selected number of proteins can be induced on platelet activation. The full complexity of the platelet genome is now just being revealed and may open the possibility for improved diagnosis and therapy of many haemostatic and thrombotic disorders.

Protein synthesis by platelets: historical and new perspectives

In the late 1960s, numerous investigators independently demonstrated that platelets are capable of synthesizing proteins. Studies continued at a steady pace over the next 30 years and into the 21st century. Collectively, these investigations confirmed that platelets synthesize proteins and that the pattern of protein synthesis changes in response to cellular activation. More recent studies have characterized the mechanisms by which platelets synthesize proteins and have shown that protein synthesis alters the phenotype and functions of platelets. Here, we chronologically review our increased understanding of protein synthetic responses in platelets and discuss how the field may evolve over the next decade.

Microparticle-mediated thrombin generation assay: increased activity in patients with recurrent thrombosis

BACKGROUND

Circulating cell-derived microparticles (MP) are important players in thrombogenesis, attributed in part to tissue factor (TF) carried on them. We developed MP-mediated thrombin generation assay (TGA) and measured a series of patients with thrombosis (TBS) and normal controls (NC).

METHODS

MP were isolated from plasma of 66 patients with TBS and 34 NC. The MP were resuspended in normal pooled particle-free plasma (PFP) containing corn trypsin inhibitor (to inhibit contact pathway). MP mediated TGA yields three parameters: lag time, peak and rate. This method is not influenced by anticoagulant therapy. Of the TBS patients, 41 had only a single thrombosis (S-TBS) and 25 had recurrences (R-TBS) within a 5-year period. In parallel, MP were quantitated by flow cytometry, and cell origin was determined: endothelial cells (EMP), leukocytes (LMP), red cells (RMP) and platelets (PMP).

RESULTS

MP from all TBS patients exhibited higher thrombin generation than NC by all three TGA parameters. R-TBS had significantly greater TGA values than S-TBS, reflected in higher peak and rate, and shorter lag time. MP numbers were also higher in TBS vs. NC, for all MP subtypes, and were significantly higher in R-TBS than S-TBS (except LMP). All MP levels correlated with thrombin generation (P < 0.0001), most closely between PMP and peak (R = 0.47) and rate (R = 0.43).

CONCLUSIONS

MP-mediated TGA is a novel way to assess functional procoagulant activity of MP. Enhanced MP-mediated TGA was demonstrated in TBS patients, and significantly higher activity in R-TBS. These findings support a major role of MP in thrombogenesis.