Michael A.S. Taboski scite author profile

The vascular endothelial cells line the inner surface of blood vessels and function to maintain blood fluidity by producing the protease plasmin that removes blood clots from the vasculature, a process called fibrinolysis. Plasminogen receptors play a central role in the regulation of plasmin activity. The protein complex annexin A2 heterotetramer (AIIt) is an important plasminogen receptor at the surface of the endothelial cell. AIIt is composed of 2 molecules of annexin A2 (ANXA2) bound together by a dimer of the protein S100A10. Recent work performed by our laboratory allowed us to clarify the specific roles played by ANXA2 and S100A10 subunits within the AIIt complex, which has been the subject of debate for many years. The ANXA2 subunit of AIIt functions to stabilize and anchor S100A10 to the plasma membrane, whereas the S100A10 subunit initiates the fibrinolytic cascade by colocalizing with the urokinase type plasminogen activator and receptor complex and also providing a common binding site for both tissue-type plasminogen activator and plasminogen via its C-terminal lysine residue. The AIIt mediated colocalization of the plasminogen activators with plasminogen results in the rapid and localized generation of plasmin to the endothelial cell surface, thereby regulating fibrinolysis. (Blood. 2011;118(18):4789-4797) IntroductionThe vascular endothelium consists of a single cell layer lining all vessels that separates the blood from the tissues. It is estimated to be composed of ϳ 10 13 cells, representing a weight of 1.5 kg and an area of 4000 to 7000 m 2 . 1 Endothelial cells play a role in primary hemostasis, coagulation, fibrinolysis, and regulation of vasomotor tone. In addition to regulating the flow of nutrients, the vascular endothelium regulates many diverse biologically active molecules. These functions of the endothelium are achieved through the presence of membrane-bound receptors for various proteins, lipidtransporting complexes, hormones, and metabolites, as well as through specific extracellular proteins and receptors that regulate cell-cell and cell-matrix interactions. 2 Whereas exposure to inflammatory and/or septic stimuli rapidly leads to procoagulant behavior, unperturbed endothelial cells provide an anticoagulant environment. After vascular insult, endothelial cells express tissue factor and initiate the coagulation cascade that results in thrombin activation and fibrin clot deposition. At the same time, anticoagulant pathways and fibrinolysis are activated to avoid disseminated coagulation and to also limit fibrin accumulation. [3][4][5] Fibrinogen is a large glycoprotein that constitutes the main component of a fibrin clot. Each fibrinogen molecule is composed of 2 sets of A␣-, B␤-, and ␥-polypeptide chains that form a protein containing 2 distal D regions connected to a central E region by a coiled-coil segment. 6 Fibrin is produced on cleavage of the fibrinopeptides by thrombin, which results in the formation of double-stranded half-staggered oligomers that lengthen into protofibrils...

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An Anchor Site–Type Defect in Human Telomerase That Disrupts Telomere Length Maintenance and Cellular Immortalization

Moriarty

Ward

Taboski

et al. 2005

MBoC

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Telomerase-mediated telomeric DNA synthesis is important for eukaryotic cell immortality. Telomerase adds tracts of short telomeric repeats to DNA substrates using a unique repeat addition form of processivity. It has been proposed that repeat addition processivity is partly regulated by a telomerase reverse transcriptase (TERT)-dependent anchor site; however, anchor site-mediating residues have not been identified in any TERT. We report the characterization of an N-terminal human TERT (hTERT) RNA interaction domain 1 (RID1) mutation that caused telomerase activity defects consistent with disruption of a template-proximal anchor site, including reduced processivity on short telomeric primers and reduced activity on substrates with nontelomeric 5' sequences, but not on primers with nontelomeric G-rich 5' sequences. This mutation was located within a subregion of RID1 previously implicated in biological telomerase functions unrelated to catalytic activity (N-DAT domain). Other N-DAT and C-terminal DAT (C-DAT) mutants and a C-terminally tagged hTERT-HA variant were defective in elongating short telomeric primers, and catalytic phenotypes of DAT variants were partially or completely rescued by increasing concentrations of DNA primers. These observations imply that RID1 and the hTERT C terminus contribute to telomerase's affinity for its substrate, and that RID1 may form part of the human telomerase anchor site.

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The N-terminus of hTERT contains a DNA-binding domain and is required for telomerase activity and cellular immortalization

Sealey

Zheng

Taboski

et al. 2009

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Telomerase defers the onset of telomere damage-induced signaling and cellular senescence by adding DNA onto chromosome ends. The ability of telomerase to elongate single-stranded telomeric DNA depends on the reverse transcriptase domain of TERT, and also relies on protein:DNA contacts outside the active site. We purified the N-terminus of human TERT (hTEN) from Escherichia coli, and found that it binds DNA with a preference for telomeric sequence of a certain length and register. hTEN interacted with the C-terminus of hTERT in trans to reconstitute enzymatic activity in vitro. Mutational analysis of hTEN revealed that amino acids Y18 and Q169 were required for telomerase activity in vitro, but not for the interaction with telomere DNA or the C-terminus. These mutants did not reconstitute telomerase activity in cells, maintain telomere length, or extend cellular lifespan. In addition, we found that T116/T117/S118, while dispensable in vitro, were required for cellular immortalization. Thus, the interactions of hTEN with telomere DNA and the C-terminus of hTERT are functionally separable from the role of hTEN in telomere elongation activity in vitro and in vivo, suggesting other roles for the protein and nucleic acid interactions of hTEN within, and possibly outside, the telomerase catalytic core.

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