Flow‐mediated plasticity in the expression of stickleback nesting glue genes

Nest construction is an essential component of the reproductive behavior of many species, and attributes of nests – including their location and structure – have implications for both their functional capacity as incubators for developing offspring, and their attractiveness to potential mates. To maximize reproductive success, nests must therefore be suited to local environmental conditions. Male three‐spined sticklebacks (Gasterosteus aculeatus) build nests from collected materials and use an endogenous, glue‐like multimeric protein – “spiggin” – as an adhesive. Spiggin is encoded by a multigene family, and differential expression of spiggin genes potentially allows plasticity in nest construction in response to variable environments. Here, we show that the expression of spiggin genes is affected significantly by both the flow regime experienced by a fish and its nesting status. Further, we show the effects of flow on expression patterns are gene‐specific. Nest‐building fish exhibited consistently higher expression levels of the three genes under investigation (Spg‐a, Spg‐1, and Spg‐2) than non‐nesting controls, irrespective of rearing flow treatment. Fish reared under flowing‐water conditions showed significantly increased levels of spiggin gene expression compared to those reared in still water, but this effect was far stronger for Spg‐a than for Spg‐1 or Spg‐2. The strong effect of flowing water on Spg‐a expression, even among non‐nesters, suggests that the increased production of spiggin – or of spiggin rich in the component contributed by Spg‐a – may allow more rapid and/or effective nest construction under challenging high flow conditions.     

Favorable 2′-substitution in the loop region of a thrombin-binding DNA aptamer

Simple 2′-OMe-chemical modification in the loop region of the 15mer G-rich DNA sequence GGTTGGTGTGGTTGG is reported. The G-quadruplex structure of this thrombin-binding aptamer (TBA), is stabilized by single modifications (T?→?2′-OMe-U), depending on the position of the modification. The structural stability also renders significantly increased inhibition of thrombin-induced fibrin polymerization, a process closely associated with blood-clotting.     

纤维蛋白胶-抗肿瘤药物缓释系统的临床应用进展

纤维蛋白胶作为药物缓释载体的研究已经引起各国研究人员的注意,其中纤维蛋白胶—抗肿瘤药物缓释系统的研究取得了较好的效果,倍受瞩目。本文对纤维蛋白胶—抗肿瘤药物缓释系统的临床应用进展进行了总结。     

Probing interactions between the coagulants thrombin, Factor XIII, and fibrin(ogen)

Thrombin cleaves fibrinopeptides A and B from fibrinogen leading to the formation of a fibrin network that is later covalently crosslinked by Factor XIII (FXIII). Thrombin helps activate FXIII by catalyzing hydrolysis of the FXIII activation peptides (AP). In the current work, the role of exosites in the ternary thrombin-FXIII-fibrin(ogen) complex was further explored. Hydrolysis studies indicate that thrombin predominantly utilizes its active site region to bind extended Factor XIII AP (FXIII AP 33-64 and 28-56) leaving the anion-binding exosites for fibrin(ogen) binding. The presence of fibrin-I leads to improvements in the K(m) for hydrolysis of FXIII AP (28-41), whereas peptides based on the cardioprotective FXIII V34L sequence exhibit less reliance on this cofactor. Surface plasmon resonance measurements reveal that d-Phe-Pro-Arg-chloromethylketone-thrombin binds to fibrinogen faster than to FXIII a(2) and dissociates from fibrinogen more slowly than from FXIII a(2). This system of thrombin exosite interactions with differing affinities promotes efficient clot formation.     

Purification and characterization of a novel thermoacid-stable fibrinolytic enzyme from <Emphasis Type="Italic">Staphylococcus</Emphasis> sp. strain AJ isolated from Korean salt-fermented Anchovy-<Emphasis Type="Italic">joet</Emphasis>

A novel fibrinolytic enzyme (AJ) was purified from Staphylococcus sp. strain AJ screened from Korean salt-fermented Anchovy-jeot. Relative molecular weight of AJ was determined as 26 kDa by using SDS-PAGE and fibrin zymography. Based on a 2D gel, AJ was found to consist of three active isoforms (pI 5.5–6.0) with the same N-terminal amino acid sequence. AJ exhibited optimum pH and temperature at 2.5–3.0 and 85°C, respectively. AJ kept 85% of the initial activity after heating at 100°C for 20 min on the zymogram gel. The Michaelis constant (K _m) and K _cat values of AJ towards α-casein were 0.38 mM and 19.73 s⁻¹, respectively. AJ cleaved the Aα-chain of fibrinogen but did not affect the Bβ- and γ-chains, indicating that it is an α-fibrinogenase. The fibrinolytic activity was inhibited by diisopropyl fluorophosphate, indicating AJ is a serine protease. Interestingly, AJ was very stable at acidic condition, SDS, and heat (100°C), whereas it was easily degraded at neutral and alkaline conditions. In particular, AJ formed an active homo-dimer in the pH range from 7.0 to 8.0. To our knowledge, a similar combination of acid and heat stability has not yet been reported for other fibrinolytic enzymes.     

Molecular aspects in clinical hemostasis research at Karolinska Institutet

The development of hemostasis research at Karolinska Institutet is described, focusing first on the initial findings of the fibrinogen structure and the hereditary bleeding disorders, hemophilia A and von Willebrand’s disease. Basic research has focused on new biomarkers for cardiovascular/thromboembolic disorders, such as myocardial infarction and stroke, including preeclampsia and diabetes, with studies on the importance of decreased fibrinolysis in these disorders. Since long, the structure of the fibrin network has been evaluated, and recently the influence of aspirin and new thrombin and factor Xa inhibitors has been investigated. Research on the contact pathway of coagulation has also started at the Unit.     

Sphingosine-1-phosphate markedly induces matrix metalloproteinase and integrin-dependent human endothelial cell invasion and lumen formation in three-dimensional collagen and fibrin matrices

Endothelial cell invasion is a key step in angiogenic blood vessel formation. Sphingosine-1-phosphate (S1P) has been previously reported to play a role in endothelial cell proliferation, survival, migration, and angiogenesis. Here, we examine the ability of S1P to regulate human endothelial cell invasion into three-dimensional collagen or fibrin matrices. We show that S1P potently stimulated human endothelial cell invasion, lumen formation, and branching morphogenesis in collagen, and fibrin matrices, (5- and 15-fold increases in invasion were observed, respectively). The S1P-induced invasion response was pertussis-toxin sensitive and completely dependent on integrins. Addition of integrin blocking reagents revealed that the alpha2beta1 integrin regulated invasion in collagen matrices, while a combination of alphavbeta3 and alpha5beta1 integrins regulated invasion in fibrin. Additionally, the S1P-induced invasion response was dependent on matrix metalloproteinases (MMPs). Tissue inhibitor of metalloproteinase-3 (TIMP-3) was the only physiologic inhibitor of metalloproteinases that completely inhibited the potent stimulation of invasion induced by S1P. In contrast, TIMP-1 had no blocking effect on invasion or morphogenesis, while TIMP-2 and TIMP-4 partially reduced invasion but completely blocked lumen formation events. Collectively, these data reveal a marked ability of S1P to induce metalloproteinase- and integrin-dependent human endothelial cell invasion and morphogenesis in both collagen and fibrin three-dimensional matrices, the two most physiologically relevant matrices for angiogenesis.     

Potential microbiological hazards in the production of refined paper products for food applications

This study sought to investigate the significance of raw materials (starch-based glues, raw material papers) at different microbiologically critical stages in the manufacturing process of refined paper products. The study examined the occurrence of microorganisms in the process and in end-product samples. Microbiological surveys verified that the production and use of pasteurized starch-based glue was the most important factor threatening the process hygiene and product safety. Subsequently, the production and use of starch-based glue was changed, and a follow-up programme targeting the microbiological quality of glue was developed as part of a hygiene and safety management system. A total of 33 spore-forming bacterial and 15 enterobacterial isolates were ribotyped, and 22 and 10 different ribogroups (ribotypes), respectively, were generated. These isolates from starch-based glue, raw material paper and end products were atypical and, thus, in many cases physiological, chemotaxonomic (FAME) and molecular (partial 16S rDNA) results did not correspond. The most common spore-forming bacteria (55% of the isolates) were Paenibacillus sp. and within this genus several new species were also proposed. The most common enterobacteria (87%) were Enterobacter cloacae and Citrobacter freundii belonging to bacteria in hazard group 2, or species closely related to them. It was demonstrated that the same spore-forming bacteria (ribotypes) were present in both the glue samples and the end products (45% of isolates). All RiboPrint patterns were saved at the VTT identification library for future use.     

Aggregation of fibrinogen molecules by metal ions

The ability of metal ions to cause physical aggregation of neutral solutions of bovine fibrinogen has been studied. Three categories were found: (a) ions (such as Ca²⁺, Mg²⁺ and Mn²⁺) which did not cause aggregation even when present in 1–100 mm concentrations: (b) ions (such as Fe²⁺, Cu²⁺ and Ni²⁺) which caused aggregation in the 0–10 mm concentration range, (c) ions (such as Hg²⁺, Zn²⁺, Cr³⁺, La³⁺) which caused aggregation in the 0–1000 μm concentration range. Aggregation occurs immediately the metal ion is brought into contact with the fibrinogen, and product formation reaches a steady state within 5 min. With the exception of Zn²⁺, all the ions that caused aggregation exhibited a threshold concentration below which no observable aggregation took place. The threshold concentration for Hg²⁺, the most effective ion studied, was 6 μm. Addition of excess EDTA caused resolubilization of the aggregated fibrinogen due to removal of the metal ions. Aggregation is thus thought to be a physical process initiated by binding of metal ions to those carboxyl groups in fibrinogen responsible for keeping the monomers apart in solution. The aggregation does not involve prior proteolytic degradation of the fibrinogen.     

Gelatinolytic and fibrinolytic activity in fresh-frozen plasma

Fresh-frozen plasma (FFP) was evaluated for gelatinolytic and fibrinolytic activity. Gelatin zymography revealed that gelatinase A (MMP-2) was constitutively present in FFP whereas gelatinase B (MMP-9) was present at variable levels. The presence of MMP-9 likely represents differential release from neutrophils during FFP collection or processing. Although fibrin matrices generated from FFP or freshly prepared plasma contained characteristic crosslinked - dimers and -monomers, matrices generated from FFP were resistant to spontaneous plasmin-dependent fibrinolysis. This observation likely stems from the plasminogen activator instability and could potentially lead to a hypofibrinolytic state. The impact of these in vitro findings to protease balance in patients receiving multiple FFP doses remains to be determined.