Steroidogenic Acute Regulatory Protein-related Transfer Research Articles

Transcription Factor RUNX1 Regulates Pctp (Phosphatidylcholine Transfer Protein) in Platelets: A Potential Role in Regulating Platelet Function

Transcription factor (TF) mutations are increasingly recognized to play a major role in inherited platelet abnormalities. RUNX1, a critical hematopoietic TF, acts in a combinatorial manner with other TFs to regulate numerous megakaryocyte (MK)/platelet genes. Human RUNX1 haplodeficiency is associated with thrombocytopenia, numerous platelet function defects, and increased leukemia risk. We have previously described a patient with a heterozygous RUNX1 nonsense mutation in the conserved runt domain necessary for DNA binding (Sun et al Blood 2004;103;948-54). The patient's platelet abnormalities included impaired aggregation and secretion in response to multiple agonists, granule deficiency, and decreased phosphorylation of myosin light chain and pleckstrin, activation of GPIIb-IIIa, 12-HETE production, and platelet protein kinase C-θ. Transcript expression profiling of patient platelets (Sun et al, J Thromb Haemost 2007;5:146-54) showed numerous genes were significantly downregulated, including myosin light chain (MYL9), platelet factor 4 (PF4), protein kinase C-θ (PRCKQ), and 12-lipoxygenase (ALOX12); these have been shown by us to be regulated by RUNX1. The profiling data also showed 10-fold downregulation of phosphatidylcholine transfer protein (PCTP) gene (fold change ratio 0.09, p=0.02) in the patient compared with normal controls. PCTP is a member of the START (Steroidogenic Acute Regulatory Protein-Related Transfer) domain superfamily and is responsible for the intermembrane transfer of phosphatidylcholine (PC), a major plasma membrane phospholipid. Several findings indicate that PCTP is important for platelet function. PC is the main fraction of platelet phospholipids and source of arachidonic acid (AA) upon activation. Release of free AA from PC is the rate-limiting step in thromboxane production. PC is also a substrate for phospholipase D, which yields phosphatidic acid that can generate the second messenger diacylglycerol. Importantly, platelet PCTP has recently been demonstrated to have a major role in the racial differences in platelet responses - increased PCTP expression has been linked to the higher platelet aggregation and calcium mobilization induced by thrombin receptor protease-activated receptor 4 (PAR4) in blacks as compared to whites (Edelstein et al Nat Med 2013;19:1609-16). Little is known regarding the regulation of PCTP in MKs/platelets.Based on the decreased platelet PCTP expression in our patient, we pursued the hypothesis that PCTP is regulated by RUNX1. Corrected total cellular immunofluorescence with anti-PCTP antibody showed significantly reduced platelet PCTP expression by 58% in our patient compared to a normal control. In silico analysis revealed 5 RUNX1 consensus binding sites up to 995 bp of the PCTP 5' upstream region from ATG. To assess for interaction of RUNX1 with the PCTP promoter, chromatin immunoprecipitation (ChIP) assay with anti-RUNX1 antibody was performed using human erythroid leukemia (HEL) cells treated with phorbol 12-myristate 13-acetate (PMA) for 24 hours to induce megakaryocytic transformation. The ChIP studies showed RUNX1 binding to PCTP chromatin in the regions encompassing RUNX1 binding sites 1 (-232/-227) and 2 (-345/-340), at site 3 (-519/-514), and encompassing sites 4 and 5 (-861/-856, -884/-879). Electrophoretic mobility shift assay (EMSA) using PMA-treated HEL cell nuclear extracts showed RUNX1 binding to DNA probes (28-37 bp) containing site 1 (-232/-227) and both sites 4 and 5 (-861/-856, -884/-879). To assess the effect of modulating RUNX1 expression on PCTP expression, PMA-treated HEL cells were transfected with RUNX1 overexpression plasmid or siRNA. PCTP mRNA and protein expression were increased with RUNX1 overexpression and reduced with RUNX1 knockdown, suggesting that PCTP is regulated by RUNX1.Conclusions: Our results provide evidence that PCTP is a direct transcriptional target of and regulated by RUNX1, and a cogent molecular mechanism for downregulation of platelet PCTP in our patient with RUNX1 haplodeficiency. Regulation of PCTP by RUNX1 may be relevant to the platelet dysfunction in RUNX1 haplodeficiency as well as to racial differences in platelet responses linked to the differential platelet expression of PCTP. DisclosuresNo relevant conflicts of interest to declare.

Interacting Proteins Dictate Function of the Minimal START Domain Phosphatidylcholine Transfer Protein/StarD2

The Star (steroidogenic acute regulatory protein)-related transfer (START) domain superfamily is characterized by a distinctive lipid-binding motif. START domains typically reside in multidomain proteins, suggesting their function as lipid sensors that trigger biological activities. Phosphatidylcholine transfer protein (PC-TP, also known as StarD2) is an example of a START domain minimal protein that consists only of the lipid-binding motif. PC-TP, which binds phosphatidylcholine exclusively, is expressed during embryonic development and in several tissues of the adult mouse, including liver. Although it catalyzes the intermembrane exchange of phosphatidylcholines in vitro, this activity does not appear to explain the various metabolic alterations observed in mice lacking PC-TP. Here we demonstrate that PC-TP function may be mediated via interacting proteins. Yeast two-hybrid screening using libraries prepared from mouse liver and embryo identified Them2 (thioesterase superfamily member 2) and the homeodomain transcription factor Pax3 (paired box gene 3), respectively, as PC-TP-interacting proteins. These were notable because the START domain superfamily contains multidomain proteins in which the START domain coexists with thioesterase domains in mammals and with homeodomain transcription factors in plants. Interactions were verified in pulldown assays, and colocalization with PC-TP was confirmed within tissues and intracellularly. The acyl-CoA thioesterase activity of purified recombinant Them2 was markedly enhanced by recombinant PC-TP. In tissue culture, PC-TP coactivated the transcriptional activity of Pax3. These findings suggest that PC-TP functions as a phosphatidylcholine-sensing molecule that engages in diverse regulatory activities that depend upon the cellular expression of distinct interacting proteins.

Structural Insight into the Self-Sacrifice Mechanism of Enediyne Resistance

The recent discovery of the first "self-sacrifice" mechanism for bacterial resistance to the enediyne antitumor antibiotics, where enediyne-induced proteolysis of the resistance protein CalC inactivates both the highly reactive metabolite and the resistance protein, revealed yet another ingenious bacterial mechanism for controlling reactive metabolites. As reported herein, the first 3D structures of CalC and CalC in complex with calicheamicin (CLM) divulge CalC to be a member of the steroidogenic acute regulatory protein (StAR)-related transfer (START) domain superfamily. In contrast to previous studies of proteins known to bind DNA-damaging natural products ( e.g ., bleomycins, mitomycins, and nine-membered chromoprotein enediynes), this is the first demonstrated involvement of a START domain fold. Consistent with the CalC self-sacrifice mechanism, CLM in complex with CalC is positioned for direct hydrogen abstraction from Gly113 to initiate the oxidative proteolysis-based resistance mechanism. These structural studies also illuminate, for the first time, a small DNA-binding region within CalC that may serve to localize CalC to the enediyne target (DNA). Given the role of START domains in nuclear/cytosolic transport and translocation, this structural study also may implicate START domains as post-endocytotic intracellular chaperones for enediyne-based therapeutics such as MyloTarg.

Structure of human phosphatidylcholine transfer protein in complex with its ligand.

Phosphatidylcholines (PtdChos) comprise the most common phospholipid class in eukaryotic cells. In mammalian cells, these insoluble molecules are transferred between membranes by a highly specific phosphatidylcholine transfer protein (PC-TP) belonging to the steroidogenic acute regulatory protein related transfer (START) domain superfamily of hydrophobic ligand-binding proteins. The crystal structures of human PC-TP in complex with dilinoleoyl-PtdCho or palmitoyl-linoleoyl-PtdCho reveal that a single well-ordered PtdCho molecule occupies a centrally located tunnel. The positively charged choline headgroup of the lipid engages in cation-pi interactions within a cage formed by the faces of three aromatic residues. These binding determinants and those for the phosphoryl group may be exposed to the lipid headgroup at the membrane-water interface by a conformational change involving the amphipathic C-terminal helix and an Omega-loop. The structures presented here provide a basis for rationalizing the specificity of PC-TP for PtdCho and may identify common features used by START proteins to bind their hydrophobic ligands.