Constantino Martínez

Molecular bases of defective signal transduction in the platelet P2Y12 receptor of a patient with congenital bleeding

We have identified structural attributes required for signal transduction through a seven-transmembrane-domain receptor. Platelets from a patient (AC) with a congenital bleeding disorder had normal shape change but reduced and reversible aggregation in response to 4 μM ADP, similar to normal platelets with blocked P2Y12 receptor. The response to 20 μM ADP, albeit still decreased, was more pronounced and was reduced by a P2Y12 antagonist, indicating some residual receptor function. ADP failed to lower the adenylyl cyclase activity stimulated by prostaglandin E1 in the patients platelets, even though the number and affinity of 2-methylthioadenosine 5′-[33P]diphosphate-binding sites was normal. Analysis of the patients P2Y12 gene revealed a G-to-A transition in one allele, changing the codon for Arg-256 in the sixth transmembrane domain to Gln, and a C-to-T transition in the other allele, changing the codon for Arg-265 in the third extracellular loop to Trp. Neither mutation interfered with receptor surface expression but both altered function, since ADP inhibited the forskolin-induced increase of cAMP markedly less in cells transfected with either mutant P2Y12 as compared with wild-type receptor. These studies delineate a region of P2Y12 required for normal function after ADP binding.

A prototypic platelet septin and its participation in secretion

Studies are presented characterizing platelet CDCrel-1, a protein expressed to high levels by megakaryocytes and belonging to a family of conserved proteins, termed septin. Septin filaments originally were identified in yeast as essential for budding but have become increasingly associated with processes in higher eukaryotic cells involving active membrane movement such as cytokinesis and vesicle trafficking. Direct proof of an in vivo function for septins in higher eukaryotes is limited to the characterization of the Drosophila septin, termed PNUT. We present studies identifying platelet CDCrel-1 as a protein kinase substrate in the presence of known platelet agonists. The immunopurification of CDCrel-1 revealed it to be part of a macromolecular complex containing a protein involved in platelet secretion, syntaxin 4. Moreover, CDCrel-1 was localized in situ to areas surrounding platelet-storage granules. The relevance of CDCrel-1 to normal platelet function was established with the characterization of platelets from a CDCrel-1Null mouse. As compared with platelets from wild-type littermates, CDCrel-1Null platelets aggregate and release stored [14C]serotonin in the presence of subthreshold levels of collagen. These results provide new insights into the mechanisms regulating platelet secretion and identify platelet septins as a protein family contributing to membrane trafficking within the megakaryocyte and platelet.

Apigenin inhibits platelet adhesion and thrombus formation and synergizes with aspirin in the suppression of the arachidonic acid pathway.

Previous studies using washed platelets demonstrated that certain flavonoids inhibit platelet function through several mechanisms including blockade of TxA(2) receptors (TPs). We aimed to analyze the binding capacity of flavonoids to TPs in platelet rich plasma (PRP), investigated their effect in flowing blood, and evaluated the ability of apigenin to improve the efficacy of aspirin in the inhibition of platelet aggregation. The binding of flavonoids to TPs in PRP was explored using binding assays and the TP antagonist [ (3)H]SQ29548. Effects of flavonoids on platelet adhesion were assessed using arterial subendothelium with annular plate perfusion chambers, and global evaluation of apigenin on high-shear-dependent platelet function was determined by the PFA-100. To evaluate the ability of apigenin to potentiate the effect of aspirin, arachidonic acid-induced platelet aggregation was measured prior to and after consumption of subaggregatory doses of aspirin in the presence or absence of apigenin. Binding assays revealed that apigenin was an efficient competitor of [ (3)H]SQ29548 binding to PRP ( K i = 155.3 +/- 65.4 microM), and perfusion studies showed that apigenin, genistein, and catechin significantly diminished thrombus formation when compared to control (26.2 +/- 3.8, 33.1 +/- 5.2, and 26.2 +/- 5.2 vs 76.6 +/- 2.6%, respectively; p < 0.05). Apigenin, similarly to the TP antagonist SQ29548, significantly prolonged collagen epinephrine-induced PFA-100 closure time in comparison to the control and, when added to platelets that had been exposed in vivo to aspirin, potentiated its inhibitory effect on platelet aggregation. The inhibitory effect of some flavonoids in the presence of plasma, particularly apigenin, might in part rely on TxA(2) receptor antagonism. There is a clear increase in the ex vivo antiplatelet effect of aspirin in the presence of apigenin, which encourages the idea of the combined use of aspirin and certain flavonoids in patients in which aspirin fails to properly suppress the TxA(2) pathway.

Human septin–septin interactions as a prerequisite for targeting septin complexes in the cytosol

Septins are a cytosolic GTP-binding protein family first characterized in yeast, but gaining increasing recognition as critical protagonists in higher eukaryotic cellular events. Mammalian septins have been associated with cytokinesis and exocytosis, along with contributing to the development of neurological disorders. Ten different septins, divided into four groups, have been identified in mammals, and individual septins are capable of interacting with each other to form macromolecular complexes. The present study characterizes the structural requirements for human septin-septin interactions using a yeast two-hybrid system. We focus on three septins that are highly expressed in platelets and neurons, SEPT4 [previously designated H5, CDCrel-2 (cell-division-control-related-2), PNUTL2], SEPT5 (CDCrel-1, PNUTL1) and SEPT8 (KIAA0202). Each of these three septins contains a characteristic domain structure consisting of unique N- and C-termini, and a central core domain conserved among the family of proteins. The yeast two-hybrid system yielded data consistent with a model where each of the three septins can interact with itself (homotypic assembly) or with one of the other septins (heterotypic assembly). For SEPT5 and SEPT8, the results illustrate a model whereby heterotypic septin assembly is dependent on the conserved central core domain and homotypic interactions require the N- and C-termini of each protein. We also characterized a model in which the proper cellular localization of SEPT5 and SEPT8 requires concomitant expression of both proteins. Co-transfection of SEPT5 and SEPT8 results in both proteins targeted to a vesicular-like location. Therefore the cellular repertoire of human septins has an impact on function by targeting septin macromolecular complexes to specific cellular locations.

Polymorphisms of P‐selectin glycoprotein ligand‐1 are associated with neutrophil–platelet adhesion and with ischaemic cerebrovascular disease

P‐selectin glycoprotein ligand (PSGL‐1) shares common features with platelet glycoprotein Ibα. A recently described polymorphism in this receptor that results in a variable number of tandem repeats (VNTR) sequence present either 16, 15 or 14 times (alleles A, B or C) could, similar to GPIbα, be functionally relevant. The allelic frequency of this polymorphism was investigated in 469 individuals from the south of Spain, and was similar to that previously described in other Caucasian populations: 85% A, 14% B and 1% C alleles. We identified two new polymorphisms genetically linked to the C isoform, resulting in the Ser273Phe and Met274Val changes. To assess the functional consequence of the polymorphisms in the receptor, we performed flow cytometric analysis of P‐selectin dependent neutrophil–platelet interaction. Neutrophils carrying the shortest C allele and the amino acid variations in residues 273 and 274 exhibited a significantly lower capacity to bind activated platelets than A/B and A/A samples (mean fluorescence intensity of CD42b+ neutrophils 262 versus 303 and 319 respectively, P < 0·05). The distribution of the VNTR was analysed in three case–control studies including 104 cerebrovascular (CVD), 101 coronary heart disease (CHD) and 150 deep venous thrombosis (DVT) patients. The results showed that smaller (B and C) alleles seem to be associated with a lower risk of developing CVD (P = 0·008) but not to be related to CHD or DVT. In conclusion, polymorphisms of the PSGL‐1 receptor may influence the neutrophil–platelet binding, and represent a risk factor for CVD.

Amelioration of the severity of heparin-binding antithrombin mutations by posttranslational mosaicism

The balance between actions of procoagulant and anticoagulant factors protects organisms from bleeding and thrombosis. Thus, antithrombin deficiency increases the risk of thrombosis, and complete quantitative deficiency results in intrauterine lethality. However, patients homozygous for L99F or R47C antithrombin mutations are viable. These mutations do not modify the folding or secretion of the protein, but abolish the glycosaminoglycan-induced activation of antithrombin by affecting the heparin-binding domain. We speculated that the natural β-glycoform of antithrombin might compensate for the effect of heparin-binding mutations. We purified α- and β-antithrombin glycoforms from plasma of 2 homozygous L99F patients. Heparin affinity chromatography and intrinsic fluorescence kinetic analyses demonstrated that the reduced heparin affinity of the α-L99F glycoform (K(D), 107.9 ± 3nM) was restored in the β-L99F glycoform (K(D), 53.9 ± 5nM) to values close to the activity of α-wild type (K(D), 43.9 ± 0.4nM). Accordingly, the β-L99F glycoform was fully activated by heparin. Similar results were observed for recombinant R47C and P41L, other heparin-binding antithrombin mutants. In conclusion, we identified a new type of mosaicism associated with mutations causing heparin-binding defects in antithrombin. The presence of a fully functional β-glycoform together with the activity retained by these variants helps to explain the viability of homozygous and the milder thrombotic risk of heterozygous patients with these specific antithrombin mutations.

L718P mutation in the membrane-proximal cytoplasmic tail of β3 promotes abnormal αIIbβ3 clustering and lipid microdomain coalescence, and associates with a thrombasthenia-like phenotype

Background Support for the role of transmembrane and membrane-proximal domains of αIIbβ3 integrin in the maintenance of receptor low affinity comes from mutational studies showing that activating mutations can induce constitutive bi-directional transmembrane signaling. Design and Methods We report the functional characterization of a mutant αIIbβ3 integrin carrying the Leu718Pro mutation in the membrane-proximal region of the β3 cytoplasmic domain, identified in heterozygosis in a patient with a severe bleeding phenotype and defective platelet aggregation and adhesion. Results Transiently transfected cells expressed similar levels of normal and mutant αIIbβ3, but surface expression of mutant αvβ3 was reduced due to its retention in intracellular compartments. Cells stably expressing mutant αIIbβ3 showed constitutive binding to soluble multivalent ligands as well as spontaneous fibrinogen-dependent aggregation, but their response to DTT was markedly reduced. Fibrinogen-adherent cells exhibited a peculiar spreading phenotype with long protrusions. Immunofluorescence analysis revealed the formation of αIIbβ3 clusters underneath the entire cell body and the presence of atypical high-density patches of clustered αIIbβ3 containing encircled areas devoid of integrin that showed decreased affinity for the fluorescent lipid analog DiIC16 and were disrupted in cholesterol-depleted cells. Conclusions These findings are consistent with an important role of the membrane-proximal region of β3 in modulating αIIbβ3 clustering and lateral redistribution of membrane lipids. Since the β3 mutant was associated with a thrombasthenic phenotype in a patient carrying one normal β3 allele, these results support a dominant role of clustering in regulating integrin αIIbβ3 functions in vivo.

Antithrombin Murcia (K241E) causing antithrombin deficiency: a possible role for altered glycosylation

Background Identification of mutations in the SERPINC1 gene has revealed different mechanisms responsible for antithrombin deficiency. Deletions and nonsense mutations associate with type I deficiency. Certain missense mutations cause type II deficiency by affecting the heparin binding site or the reactive center loop, while others result in type I deficiency by intracellular retention or RNA instability. Design and Methods We studied the molecular, biochemical, proteomic and glycomic characterization of a new natural mutant (K241E) that may be classified as pleiotropic. Results The mutation caused a significant decrease in the anticoagulant activity mainly due to a reduced heparin affinity and a modification of the electrostatic potential that might explain the impaired ability of the mutant protein to form complexes with the target protease in the absence of heparin. Mass spectrometry and glycomic analyses confirmed an increased molecular weight of 800 Da in the mutant protein possibly due to core-fucosylation, provoking the loss of heparin affinity. Additionally, carriers of this mutation also have a minor mutant isoform that still followed normal glycosylation, retaining similar heparin affinity to wild-type α-antithrombin, and certain anticoagulant activity, which may explain the milder thrombotic risk of patients carrying this mutation. Similar results were observed using recombinant K241E antithrombin molecules. Conclusions Our data suggest a new mechanism involved in antithrombin type II deficiency by indirectly affecting the glycosylation of a natural variant. Additional studies are required to confirm this hypothesis.

Mammalian septin function in hemostasis and beyond

Interest in the biology of mammalian septin proteins has undergone a birth in recent years. Originally identified as critical for yeast budding throughout the 1970s, the septin family is now recognized to extend from yeast to humans and is associated with a variety of events ranging from cytokinesis to vesicle trafficking. An emerging theme for septins is their presence at sites where active membrane or cytoplasmic partitioning is occurring. Here, we briefly review the mammalian septin protein family and focus on a prototypic human and mouse septin, termed SEPT5, that is expressed in the brain, heart, and megakaryocytes. Work from neurobiology laboratories has linked SEPT5 to the exocytic complex of neurons, with implications that SEPT5 regulates neurotransmitter release. Striking similarities exist between neurotransmitter release and the platelet-release reaction, which is a critical step in platelet response to vascular injury. Work from our laboratory has characterized the platelet phenotype from mice containing a targeted deletion of SEPT5. Most strikingly, platelets from SEPT5null animals aggregate and release granular contents in response to subthreshold levels of agonists. Thus, the characterization of a SEPT5-deficient mouse has linked SEPT5 to the Platelet exocytic process and, as such, illustrates it as an important protein for regulating platelet function. Recent data suggest that platelets contain a wide repertoire of different septin proteins and assemble to form macromolecular septin complexes. The mouse platelet provides an experimental framework to define septin function in hemostasis, with implications for neurobiology and beyond.

Platelet septin complexes form rings and associate with the microtubular network

Summary.  Background: Septins are important effectors in molecular mechanisms involving membrane partitioning. To date, a growing repertoire of septins in mammals includes 13 different proteins (SEPT1 to SEPT13) that can be classified into four distinct categories based on sequence similarity. Aim: In this study, we document the human platelet septin, SEPT5, as part of a complex composed of multiple septin proteins. Results: Biochemical and immunofluorescent data place the majority of these complexes in the platelet periphery as part of the platelet circumferential band copurifying with the platelet microtubule coil and tubulin. The presence of a prominent platelet septin ring in resting platelets appears to be left intact in the activated platelet, as a similar ring structure is observed following platelet spreading on fibrinogen. The ablation of SEPT5 in the knock‐out mouse model had previously been reported to result in a platelet phenotype with aggregation using subthreshold levels of agonist. Speculation on the role of SEPT5 in the platelet‐release reaction suggested that SEPT5 regulates platelet function by association with platelet storage granules. We now report that the absence of SEPT5 results in increased ATP release from stimulated platelets. Conclusion: These studies document the presence of platelet septin complexes and validate the importance of septins for platelet physiology.