Fibrinopeptide A release is necessary for effective B:b interactions in polymerisation of variant fibrinogens with impaired A:a interactions

Fibrin polymerisation is mediated by interactions between knobs 'A' and 'B' exposed by thrombin cleavage, and holes 'a' and 'b'. We demonstrated markedly delayed thrombin-catalysed fibrin polymerisation, through B:b interactions alone, of recombinant gamma D364H-fibrinogen with impaired hole 'a'. To determine whether recombinant variant fibrinogens with no release of fibrinopeptide A (FpA) polymerise similarly to gamma D364H-fibrinoge, we examined two variant fibrinogens with substitutions altering knob 'A', A alpha 17A- and A alpha 17C-fibrinogen. We examined thrombin- or batroxobin-catalysed fibrinopeptide release by HPLC, fibrin clot formation by turbidity and fibrin clot structure by scanning electron microscopy (SEM) and compared the results of the variants with those for gamma D364H-fibrinogen. Thrombin-catalysed FpA release of A alpha 17A-fibrinogen was substantially delayed and none observed for A alpha 17C-fibrinogen; fibrinopeptide B (FpB) release was delayed for all variants. All variant fibrinogens showed substantially impaired thrombin-catalysed polymerisation; for A alpha 17A-fibrinogen it was delayed less, and for A alpha 17C more than for gamma D364H-fibrinogen. No variants polymerised with batroxobin, which exposed only knob 'A'. The inhibition of variant fibrinogens' polymerisation was dose-dependent on the concentration of either GPRP or GHRP, and both peptides that block holes 'b'. SEM showed that the variant clots from A alpha 17A- and gamma D364H-fibrinogen had uniform, ordered fibres, thicker than normal, whereas A alpha 17C-fibrinogen formed less organised clots with shorter, thinner, and tapered ends. These results demonstrate that FpA release per se is necessary for effective B:b interactions during polymerisation of variant fibrinogens with impaired A:a interactions.ArticleTHROMBOSIS AND HAEMOSTASIS. 109(2):221-228 (2013)journal articl

Nonsense-mediated mRNA decay was demonstrated in two hypofibrinogenemias caused by heterozygous nonsense mutations of FGG, Shizuoka III and Kanazawa II

We report two novel hypofibrinogenemias, Shizuoka III and Kanazawa II, which are caused by heterozygous mutations in FGG. Shizuoka III showed c.147delT and 147_149insACA in FGG exon 3 and a subsequent frameshift mutation, resulting in mature protein γ23X (native protein: γ49X), and Kanazawa II showed c.1205G>A in FGG exon 9, resulting in γ376X (native protein: γ402X). To determine whether the truncated γ-chains, γ23X and γ376X, were synthesized and participated in the assembly of fibrinogen, mutant-type cDNA vectors were transfected into Chinese hamster ovary (CHO) cells. Significant levels of mutant fibrinogen were not detected by ELISA in the culture media and cell lysates. Immunoblot analysis of cell lysates revealed that the mutant γ-chain of γ376X was observed but intact fibrinogen was not. On the other hand, mutant γ-chain was not observed in γ23X-expressing cells. To demonstrate the involvement of the mechanisms of nonsense-mediated mRNA decay (NMD), we cloned wild- and mutant-type mini-genes containing γ23 or γ376 codon and transfected these into CHO cell lines in the absence or presence of cycloheximide as an NMD inhibitor. mRNA levels were determined using real-time quantitative RT-PCR in CHO cells. In the absence of cycloheximide, levels of mRNAs transcribed from the mutant gene were lower than from the wild-type gene whereas, in the presence of cycloheximide, levels of mRNAs transcribed from the mutant gene increased dose-dependently. Finally, these results demonstrated that mRNAs containing γ23X or γ376X are degraded by the NMD system and translation of the truncated γ-chain polypeptide decrease in patients' hepatocytes, resulting in hypofibrinogenemias.ArticleTHROMBOSIS RESEARCH. 132(4):465-470 (2013)journal articl

Nonsense-mediated mRNA decay was demonstrated in two hypofibrinogenemias caused by heterozygous nonsense mutations of FGG, Shizuoka III and Kanazawa II

We report two novel hypofibrinogenemias, Shizuoka III and Kanazawa II, which are caused by heterozygous mutations in FGG. Shizuoka III showed c.147delT and 147_149insACA in FGG exon 3 and a subsequent frameshift mutation, resulting in mature protein γ23X (native protein: γ49X), and Kanazawa II showed c.1205G>A in FGG exon 9, resulting in γ376X (native protein: γ402X). To determine whether the truncated γ-chains, γ23X and γ376X, were synthesized and participated in the assembly of fibrinogen, mutant-type cDNA vectors were transfected into Chinese hamster ovary (CHO) cells. Significant levels of mutant fibrinogen were not detected by ELISA in the culture media and cell lysates. Immunoblot analysis of cell lysates revealed that the mutant γ-chain of γ376X was observed but intact fibrinogen was not. On the other hand, mutant γ-chain was not observed in γ23X-expressing cells. To demonstrate the involvement of the mechanisms of nonsense-mediated mRNA decay (NMD), we cloned wild- and mutant-type mini-genes containing γ23 or γ376 codon and transfected these into CHO cell lines in the absence or presence of cycloheximide as an NMD inhibitor. mRNA levels were determined using real-time quantitative RT-PCR in CHO cells. In the absence of cycloheximide, levels of mRNAs transcribed from the mutant gene were lower than from the wild-type gene whereas, in the presence of cycloheximide, levels of mRNAs transcribed from the mutant gene increased dose-dependently. Finally, these results demonstrated that mRNAs containing γ23X or γ376X are degraded by the NMD system and translation of the truncated γ-chain polypeptide decrease in patients' hepatocytes, resulting in hypofibrinogenemias.ArticleTHROMBOSIS RESEARCH. 132(4):465-470 (2013)journal articl

Taurine supplementation enhances endurance capacity by delaying blood glucose decline during prolonged exercise in rats

Taurine enhances physical performance; however, the underlying mechanism remains unclear. This study examined the effect of taurine on the overtime dynamics of blood glucose concentration (BGC) during endurance exercise in rats. Male F344 rats were subjected to transient treadmill exercise until exhaustion following 3 weeks of taurine supplementation or non-supplementation (TAU and CON groups). Every 10 min during exercise, BGC was measured in blood collected through cannulation of the jugular vein. Gluconeogenesis-, lipolysis-, and fatty acid oxidation-related factors in the plasma, liver, and skeletal muscles were also analyzed after 120-min run. Exercise time to exhaustion was significantly longer with taurine supplementation. BGC in the two groups significantly increased by 40 min and gradually and significantly decreased toward the respective exhaustion point. The decline in BGC from the peak at 40 min was significantly slower in the TAU group. The time when the once-increased BGC regressed to the 0-time level was significantly and positively correlated with exercise time until exhaustion. At the 120-min point, where the difference in BGC between the two groups was most significant, plasma free fatty acid concentration and acetyl-carnitine and N-acetyltaurine concentrations in skeletal muscle were significantly higher in the TAU group, whereas glycogen and glucogenic amino acid concentrations and G6Pase activity in the liver were not different between the two groups. Taurine supplementation enhances endurance capacity by delaying the decrease in BGC toward exhaustion through increases of lipolysis in adipose tissues and fatty acid oxidation in skeletal muscles during endurance exercise

Fibrinopeptide A release is necessary for effective B:b interactions in polymerisation of variant fibrinogens with impaired A:a interactions

Fibrin polymerisation is mediated by interactions between knobs 'A' and 'B' exposed by thrombin cleavage, and holes 'a' and 'b'. We demonstrated markedly delayed thrombin-catalysed fibrin polymerisation, through B:b interactions alone, of recombinant gamma D364H-fibrinogen with impaired hole 'a'. To determine whether recombinant variant fibrinogens with no release of fibrinopeptide A (FpA) polymerise similarly to gamma D364H-fibrinoge, we examined two variant fibrinogens with substitutions altering knob 'A', A alpha 17A- and A alpha 17C-fibrinogen. We examined thrombin- or batroxobin-catalysed fibrinopeptide release by HPLC, fibrin clot formation by turbidity and fibrin clot structure by scanning electron microscopy (SEM) and compared the results of the variants with those for gamma D364H-fibrinogen. Thrombin-catalysed FpA release of A alpha 17A-fibrinogen was substantially delayed and none observed for A alpha 17C-fibrinogen; fibrinopeptide B (FpB) release was delayed for all variants. All variant fibrinogens showed substantially impaired thrombin-catalysed polymerisation; for A alpha 17A-fibrinogen it was delayed less, and for A alpha 17C more than for gamma D364H-fibrinogen. No variants polymerised with batroxobin, which exposed only knob 'A'. The inhibition of variant fibrinogens' polymerisation was dose-dependent on the concentration of either GPRP or GHRP, and both peptides that block holes 'b'. SEM showed that the variant clots from A alpha 17A- and gamma D364H-fibrinogen had uniform, ordered fibres, thicker than normal, whereas A alpha 17C-fibrinogen formed less organised clots with shorter, thinner, and tapered ends. These results demonstrate that FpA release per se is necessary for effective B:b interactions during polymerisation of variant fibrinogens with impaired A:a interactions.ArticleTHROMBOSIS AND HAEMOSTASIS. 109(2):221-228 (2013)journal articl

Enhanced Functional Recovery from Spinal Cord Injury in Aged Mice after Stem Cell Transplantation through HGF Induction

The number of elderly patients with spinal cord injury (SCI) is increasing worldwide, representing a serious burden for both the affected patients and the community. Previous studies have demonstrated that neural stem cell (NSC) transplantation is an effective treatment for SCI in young animals. Here we show that NSC transplantation is as effective in aged mice as it is in young mice, even though aged mice exhibit more severe neurological deficits after SCI. NSCs grafted into aged mice exhibited better survival than those grafted into young mice. Furthermore, we show that the neurotrophic factor HGF plays a key role in the enhanced functional recovery after NSC transplantation observed in aged mice with SCI. The unexpected results of the present study suggest that NSC transplantation is a potential therapeutic modality for SCI, even in elderly patients