Evidence for the heparin-binding ability of the ascidian Xlink domain and insight into the evolution of the Xlink domain in chordates.

The vertebrate Xlink domain is found in two types of genes: lecticans and their associated hyaluronan-and-proteoglycan-binding-link-proteins (HAPLNs), which are components of the extracellular matrix, and those represented by CD44 and stabilins, which are expressed on the surface of lymphocytes. In both types of genes, Xlink functions as a hyaluronan binding domain. We have already reported that protochordate ascidians possess only the latter type of gene. The present analysis of the expression of ascidian Xlink domain genes revealed that these genes function in blood cell migration and apoptosis. While the Xlink domain is found in various metazoans, including ascidians and nematodes, hyaluronan is believed to be specific for vertebrates. In comprehensive genome surveys for hyaluronan synthase (HAS), we found no HAS gene in ascidians. We also established that hyaluronan is absent from the ascidian body biochemically. Therefore, ascidians possess the Xlink domain, but they lack HA. We recovered one ascidian Xlink domain gene that encoded a heparin-binding protein, although it shows no affinity for hyaluronan. Based on these findings, we conclude that in invertebrates, the Xlink domain serves as heparin-binding protein domain and functions in blood cell migration and apoptosis. Its binding affinity for HA might have been acquired in the vertebrate lineage.

Domain shuffling and the evolution of vertebrates.

The evolution of vertebrates has included a number of important events: the development of cartilage, the immune system, and complicated craniofacial structures. Here, we examine domain shuffling as one of the mechanisms that contributes novel genetic material required for vertebrate evolution. We mapped domain-shuffling events during the evolution of deuterostomes with a focus on how domain shuffling contributed to the evolution of vertebrate- and chordate-specific characteristics. We identified approximately 1000 new domain pairs in the vertebrate lineage, including approximately 100 that were shared by all seven of the vertebrate species examined. Some of these pairs occur in the protein components of vertebrate-specific structures, such as cartilage and the inner ear, suggesting that domain shuffling made a marked contribution to the evolution of vertebrate-specific characteristics. The evolutionary history of the domain pairs is traceable; for example, the Xlink domain of aggrecan, one of the major components of cartilage, was originally utilized as a functional domain of a surface molecule of blood cells in protochordate ancestors, and it was recruited by the protein of the matrix component of cartilage in the vertebrate ancestor. We also identified genes that were created as a result of domain shuffling in ancestral chordates. Some of these are involved in the functions of chordate structures, such as the endostyle, Reissner's fiber of the neural tube, and the notochord. Our analyses shed new light on the role of domain shuffling, especially in the evolution of vertebrates and chordates.

IRAK-4-dependent degradation of IRAK-1 is a negative feedback signal for TLR-mediated NF-kappaB activation.

The activation of interleukin 1 receptor-associated kinase (IRAK)-1 is a key event in the transmission of signals from Toll-like receptors (TLRs). The catalytic activity of the protein kinase is not essential for its ability to activate nuclear factor (NF) kappaB, because transfection of a kinase-dead mutant of IRAK-1 (IRAK-1KD) is able to activate NF-kappaB in HEK293T cells. In the present study, we observed that the effect of IRAK-1KD was impaired by simultaneous expression of IRAK-4. The effect of IRAK-4 was accompanied by the phosphorylation and degradation of IRAK-1KD. Expression of IRAK-4KD instead of IRAK-4 did not cause these events. In IRAK-4-deficient Raw264.7 macrophages that were prepared by introducing short-hairpin RNA probes, the basal level of IRAK-1 was increased markedly. Stimulation of these cells with TLR ligands did not cause the degradation of IRAK-1, which was clearly observed in the parent cells. These results suggested that the expression of IRAK-4 alone is sufficient to cause the degradation of IRAK-1; the autophosphorylation of IRAK-1 is not necessary to terminate the TLR-induced activation of NF-kappaB. IRAK-4 has an ability to induce the degradation of IRAK-1 in addition to its role as an activator of IRAK-1.

Protein kinase Cdelta binds TIRAP/Mal to participate in TLR signaling.

Toll-like receptor (TLR) family members recognize specific molecular patterns within pathogens. Signaling through TLRs results in a proximal event that involves direct binding of adaptor proteins to the receptors. We observed that TIRAP/Mal, an adaptor protein for TLR2 and TLR4, binds protein kinase Cdelta (PKCdelta). TIRAP/Mal GST-fusion protein and a TIRAP/Mal antibody were able to precipitate PKCdelta from rat peritoneal macrophage and THP1 cell lysates. Truncation mutants of TIRAP/Mal showed that the TIR domain of TIRAP/Mal is responsible for binding. TLR2- and TLR4-mediated phosphorylation of p38 MAPK, IKK, and IkappaB in RAW264.7 cells were abolished by depletion of PKCdelta. These results suggest that PKCdelta binding to TIRAP/Mal promotes TLR signaling events.