1. Transcription destabilizes centromere function
Yu Nakabayashi, Masayuki Seki Biochem Biophys Res Commun. 2022 Jan 1;586:150-156. doi: 10.1016/j.bbrc.2021.11.077. Epub 2021 Nov 25.
Bi-oriented attachment of microtubules to the centromere is a pre-requisite for faithful chromosome segregation during mitosis. Budding yeast have point centromeres containing the cis-element proteins CDE-I, -II, and -III, which interact with trans-acting factors such as Cbf1, Cse4, and Ndc10. Our previous genetic screens, using a comprehensive library of histone point mutants, revealed that the TBS-I, -II, and -III regions of nucleosomes are required for faithful chromosome segregation. In TBS-III deficient cells, peri-centromeric nucleosomes containing the H2A.Z homolog Htz1 are lacking, however, it is unclear why chromosome segregation is defective in these cells. Here, we show that, in cells lacking TBS-III, both chromatin binding at the centromere and the total amount of some of the centromere proteins are reduced, and transcription through the centromere is up-regulated during M-phase. Moreover, the chromatin binding of Cse4, Mif2, Cbf1, Ndc10, and Scm3 was reduced upon ectopic transcription through the centromere in wild-type cells. These results suggest that transcription through the centromere displaces key centromere proteins and, consequently, destabilizes the interaction between centromeres and microtubules, leading to defective chromosome segregation. The identification of new roles for histone binding residues in TBS-III will shed new light on nucleosome function during chromosome segregation.
2. Protein S is a cofactor for tissue factor pathway inhibitor
J Rosing, L F A Maurissen, S N Tchaikovski, G Tans, T M Hackeng Thromb Res. 2008;122 Suppl 1:S60-3. doi: 10.1016/S0049-3848(08)70021-5.
Protein S is a vitamin K-dependent protein that acts as a cofactor of the anticoagulant protein APC. However, protein S also exhibits anticoagulant activity in the absence of APC. Thrombin generation experiments in normal plasma and in plasma deficient in tissue factor pathway inhibitor (TFPI) and/or protein S demonstrated that protein S stimulates the inhibition of TF by TFPI. Kinetic analysis in model systems containing purified proteins showed that protein S enhances the formation of the binary FXa:TFPI complex by reducing the Ki of TFPI from approximately 4 nM to approximately 0.5 nM. Enhancement of inhibitory activity of TFPI by protein S is only observed with full-length TFPI and in the presence of a negatively charged phospholipid surface. The Ki decrease brings the TFPI concentration necessary for FXa:TFPI complex formation within range of the plasma TFPI concentration which increases FXa:TFPI complex formation and accelerates feedback inhibition of the TF pathway by enhancing the formation of the quaternary TFPI:FXa:TF:FVIIa complex. Thus, protein S is not only a cofactor of APC, but also of TFPI. A reduced TFPI cofactor activity may contribute to the increased risk of venous thrombosis in protein-S deficient individuals. Using calibrated automated thrombography we have developed two assays that enable quantification of the functional activity of the TFPI/protein S system in plasma. These assays show that the activity of the TFPI/protein S system is greatly impaired in oral contraceptive users.
3. EGF-like module pair 3-4 in vitamin K-dependent protein S: modulation of calcium affinity of module 4 by module 3, and interaction with factor X
Y Stenberg, A Muranyi, C Steen, E Thulin, T Drakenberg, J Stenflo J Mol Biol. 1999 Oct 29;293(3):653-65. doi: 10.1006/jmbi.1999.3139.
Calcium-binding epidermal growth factor (EGF)-like modules are found in numerous extracellular and membrane proteins involved in such diverse processes as blood coagulation, lipoprotein metabolism, determination of cell fate, and cell adhesion. Vitamin K-dependent protein S, a cofactor of the anticoagulant enzyme activated protein C, has four EGF-like modules in tandem with the three C-terminal modules each harbouring a Ca(2+)-binding consensus sequence. Recombinant fragments containing EGF modules 1-4 and 2-4 have two Ca(2+)-binding sites with dissociation constants ranging from 10(-8) to 10(-5) M. Module-module interactions that greatly influence the Ca(2+) affinity of individual modules have been identified. As a step towards an analysis of the structural basis of the high Ca(2+) affinity, we expressed the Ca(2+)-binding EGF pair 3-4 from human protein S. Correct folding was shown by (1)H NMR spectroscopy. Calcium-binding properties of the C-terminal module were determined by titration with chromophoric chelators; binding to the low-affinity N-terminal site was monitored by (1)H-(15)N NMR spectroscopy. At physiological pH and ionic strength, the dissociation constants for Ca(2+) binding were 1.0x10(-6) M and 4. 8x10(-3) M for modules 4 and 3, respectively, i.e. the calcium affinity of the C-terminal site was about 5000-fold higher than that of the N-terminal site. Moreover, the Ca(2+) affinity of EGF 4, in the pair 3-4, was about 9000-fold higher than that of synthetic EGF 4. The EGF modules in protein S are known to mediate the interaction with factor Xa. We have now found modules 3-4 to be involved in this interaction. However, the individual modules 3 and 4 manifested no measurable activity.
