The death-domain fold of the ASC PYRIN domain, presenting a basis for PYRIN/PYRIN recognition

The PYRIN domain is a conserved sequence motif identified in more than 20 human proteins with putative functions in apoptotic and inflammatory signalling pathways. The three-dimensional structure of the PYRIN domain from human ASC was determined by NMR spectroscopy. The structure determination reveals close structural similarity to death domains, death effector domains, and caspase activation and recruitment domains, although the structural alignment with these other members of the death-domain superfamily differs from previously predicted amino acid sequence alignments. Two highly positively and negatively charged surfaces in the PYRIN domain of ASC result in a strong electrostatic dipole moment that is predicted to be present also in related PYRIN domains. These results suggest that electrostatic interactions play an important role for the binding between PYRIN domains. Consequently, the previously reported binding between the PYRIN domains of ASC and ASC2/POP1 or between the zebrafish PYRIN domains of zAsc and Caspy is proposed to involve interactions between helices 2 and 3 of one PYRIN domain with helices 1 and 4 of the other PYRIN domain, in analogy to previously reported homophilic interactions between caspase activation and recruitment domains.     

PYRIN domains and their interactions in the apoptosis and inflammation signaling pathway

The PYRIN domain (PYD) is a well known protein interaction module and a prime mediator of the protein interactions necessary for apoptosis, inflammation and innate immune signaling pathway. Because PYD-mediated apoptosis, inflammation and innate immune processes are associated with many human diseases, studies in these areas are of great biological importance. Intensive biochemical and structural studies of PYD have been conducted in the past decade to elucidate PYD-mediated signaling events, and evaluations of the molecular structure of PYDs have shown the underlying molecular basis for the assembly of PYD-mediated complexes and for the regulation of inflammation and innate immunity. This review summarizes the structure and function of various PYDs and proposes a PYD:PYD interaction for assembly of the complexes involved in those signaling pathways.     

BRCT domains: Easy as one,two, three

BRCA1 C-terminal (BRCT) domains are integral signaling modules in the DNA damage response (DDR). Aside from their established roles as phospho-peptide binding modules, BRCT domains have been implicated in phosphorylation-independent protein interactions, DNA binding and poly(ADP-ribose) (PAR) binding. These numerous functions can be attributed to the diversity in BRCT domain structure and architecture, where domains can exist as isolated single domains or assemble into higher order homo- or hetero-domain complexes. In this review, we incorporate recent structural and biochemical studies to demonstrate how structural features allow single and tandem BRCT domains to attain a high degree of functional diversity.Key words: BRCT domain, DNA repair, phosphorylation, phospho-peptide interaction, protein interaction, DNA binding, DNA damage response     

Cutting edge: CATERPILLER: a large family of mammalian genes containing CARD,pyrin, nucleotide-binding,and leucine-rich repeat domains

Large mammalian proteins containing a nucleotide-binding domain (NBD) and C-terminal leucine-rich repeats (LRR) similar in structure to plant disease resistance proteins have been suggested as critical in innate immunity. Our interest in CIITA, a NBD/LRR protein, and recent reports linking mutations in two other NBD/LRR proteins to inflammatory disorders have prompted us to perform a search for other members. Twenty-two known and novel NBD/LRR genes are spread across eight human chromosomes, with multigene clusters occurring on 11, 16, and 19. Most of these are telomeric. Their N termini vary, but most have a pyrin domain. The genomic organization demonstrates a high degree of conservation of the NBD- and LRR-encoding exons. Except for CIITA, all the predicted NBD/LRR proteins are likely ATP-binding proteins. Some have broad tissue expression, whereas others are restricted to myeloid cells. The implications of these data on origins, expression, and function of these genes are discussed.     

The innovation triad: an EvoDevo agenda

This article introduces a special issue on evolutionary innovation and morphological novelty, two interrelated themes that have received a remarkable increase of attention over the past few years. We begin with a discussion of the question of whether innovation and novelty represent distinct evolutionary problems that require a distinct conceptualization. We argue that the mechanisms of innovation and their phenotypic results--novelty--can only be properly addressed if they are distinguished from the standard evolutionary themes of variation and adaptation, and we present arguments for making such a distinction. We propose that origination, the first formation of biological structures, is another distinct problem of morphological evolution, and that together with innovation and novelty it constitutes a conceptual complex we call the innovation triad. We define a problem agenda of the triad, which separates the analysis of the initiating conditions from the mechanistic realization of innovation, and we discuss the theoretical problems that arise from treating innovation as distinct from variation. Further, we categorize the empirical approaches that address themes of the innovation triad in recognizing four major strands of research: the morphology and systematics program, the gene regulation program, the epigenetic program, and the theoretical biology program. We provide examples of each program, giving priority to contributions in the present issue. In conclusion, we observe that the innovation triad is one of the defining topics of EvoDevo research and may represent its most pertinent contribution to evolutionary theory. We point out that an inclusion of developmental systems properties into evolutionary theory represents a shift of explanatory emphasis from the external factors of natural selection to the internal dynamics of developmental systems, complementing adaptation with emergence, and contingency with inherency.     

Molecular evolution of vertebrate Toll-like receptors: evolutionary rate difference between their leucine-rich repeats and their TIR domains

Toll-like receptors (TLRs) that initiate an innate immune response contain an extracellular leucine rich repeat (LRR) domain and an intracellular Toll IL-receptor (TIR) domain. There are fifteen different TLRs in vertebrates. The LRR domains, which adopt a solenoid structure, usually have higher rates of evolution than do the TIR globular domains. It is important to understand the molecular evolution and functional roles of TLRs from this standpoint. Both pairwise genetic distances and Ka/Ks's (the ratios between non synonymous and synonymous substitution rates) were compared between the LRR domain and the TIR domain of 366 vertebrate TLRs from 96 species (from fish to primates). In fourteen members (TLRs 1, 2, 3, 4, 5, 6, 7, 8, 9, 11/12, 13, 14, 21, and 22/23) the LRR domains evolved significantly more rapidly than did the corresponding TIR domains. The evolutionary rates of the LRR domains are significantly different among these members; LRR domains from TLR3 and TLR7 from primates to fishes have the lowest rate of evolution. In contrast, the fifteenth member, TLR10, shows no significant differences; its TIR domain is not highly conserved. The present results suggest that TLR10 may have a different function in signaling from those other members and that a higher conservation of TLR3 and TLR7 may reflect a more ancient mechanism and/or structure in the innate immune response system. Gene conversions are suggested to have occurred in platypus TLR6 and TLR10. This study provides new insight about structural and functional diversification of vertebrate TLRs.     

Cladogenesis, coalescence and the evolution of the three domains of life

In this article, we explore the large-scale structure of the tree of life by using a simple model with a constant number of species and rates of speciation that equal the rates of extinction. In addition, we discuss the consequences of horizontal gene transfer for the concept of a most recent common ancestor of all living organisms (cenancestor). A simple null hypothesis based on coalescence theory explains some features of the observed topologies of the tree of life. Simulations of genes and organismal lineages suggest that there was no single common ancestor that contained all the genes ancestral to those shared among the three domains of life. Each contemporary molecule has its own history that traces back to an individual molecular cenancestor. However, these molecular ancestors were likely to be present in different organisms and at different times.     

The newly identified human nuclear protein NXP-2 possesses three distinct domains, the nuclear matrix-binding, RNA-binding, and coiled-coil domains

Using a monoclonal antibody that recognizes a nuclear matrix protein, we selected a cDNA clone from a lambdagt11 human placenta cDNA library. This cDNA encoded a 939-amino acid protein designated nuclear matrix protein NXP-2. Northern blot analysis indicated that NXP-2 was expressed in various tissues at different levels. Forcibly expressed green fluorescent protein-tagged NXP-2 as well as endogenous NXP-2 was localized in the nucleus and distributed to the nuclear matrix. NXP-2 was released from the nuclear matrix when RNase A was included in the buffer for nuclear matrix preparation. Mapping of functional domains was carried out using green fluorescent protein-tagged truncated mutants of NXP-2. The region of amino acids 326-353 was responsible for nuclear matrix binding and contained a cluster of hydrophobic amino acids that was similar to the nuclear matrix targeting signal of acute myeloleukemia protein. The central region (amino acids 500-591) was demonstrated to be required for RNA binding by Northwestern analysis, although NXP-2 lacked a known RNA binding motif. The region of amino acid residues 682-876 was predicted to have a coiled-coil structure. The RNA-binding, nuclear matrix-binding, and coiled-coil domains are structurally separated, suggesting that NXP-2 plays important roles in diverse nuclear functions, including RNA metabolism and maintenance of nuclear architecture.     

Biochemical and genetic evidence for three transmembrane domains in the class I holin, lambda S

lambda S, the prototype class I holin gene, encodes three potential transmembrane domains in its 107 codons, whereas 21 S, the class II prototype spans only 71 codons and encodes two transmembrane domains. Many holin genes, including lambda S and 21 S, have the "dual-start" regulatory motif at the N terminus, suggesting that class I and II holins have the same topology. The primary structure of 21 S strongly suggests a bitopic "helical-hairpin" topology, with N and C termini on the cytoplasmic side of the membrane. However, lambda S chimeras with an N-terminal signal sequence show Lep-dependent function, indicating that the N-terminal domain of S requires export. Here the signal sequence chimera is shown to be sensitive to the missense change A52V, which blocks normal S function. Moreover, cysteine-modification studies in isolated membranes using a collection of S variants with single-cysteine substitutions show that the positions in the core of the 3 putative transmembrane domains of lambda S are protected. Also, S proteins with single-cysteine substitutions in the predicted cytoplasmic and periplasmic loops are more efficiently labeled in inverted membrane vesicles and whole cells, respectively. These data constitute direct evidence that the holin S(lambda) has three transmembrane domains and indicate that class I and class II holins have different topologies, despite regulatory and functional homology.     

Hint,Fhit, and GalT: function,structure, evolution,and mechanism of three branches of the histidine triad superfamily of nucleotide hydrolases and transferases

HIT (histidine triad) proteins, named for a motif related to the sequence HphiHphiHphiphi (phi, a hydrophobic amino acid), are a superfamily of nucleotide hydrolases and transferases, which act on the alpha-phosphate of ribonucleotides, and contain a approximately 30 kDa domain that is typically either a homodimer of approximately 15 kDa polypeptides with two active-sites or an internally, imperfectly repeated polypeptide that retains a single HIT active site. On the basis of sequence, substrate specificity, structure, evolution, and mechanism, HIT proteins can be classified into the Hint branch, which consists of adenosine 5'-monophosphoramide hydrolases, the Fhit branch, which consists of diadenosine polyphosphate hydrolases, and the GalT branch, which consists of specific nucleoside monophosphate transferases, including galactose-1-phosphate uridylyltransferase, diadenosine tetraphosphate phosphorylase, and adenylyl sulfate:phosphate adenylytransferase. At least one human representative of each branch is lost in human diseases. Aprataxin, a Hint branch hydrolase, is mutated in ataxia-oculomotor apraxia syndrome. Fhit is lost early in the development of many epithelially derived tumors. GalT is deficient in galactosemia. Additionally, ASW is an avian Hint family member that has evolved to have unusual gene expression properties and the complete loss of its nucleotide binding site. The potential roles of ASW and Hint in avian sexual development are discussed elsewhere. Here we review what is known about biological activities of HIT proteins, the structural and biochemical bases for their functions, and propose a new enzyme mechanism for Hint and Fhit that may account for the differences between HIT hydrolases and transferases.     

Dying for a cause: NETosis, mechanisms behind an antimicrobial cell death modality

Neutrophil extracellular traps (NETs) are chromatin structures loaded with antimicrobial molecules. They can trap and kill various bacterial, fungal and protozoal pathogens, and their release is one of the first lines of defense against pathogens. In vivo, NETs are released during a form of pathogen-induced cell death, which was recently named NETosis. Ex vivo, both dead and viable neutrophils can be stimulated to release NETs composed of either nuclear or mitochondrial chromatin, respectively. In certain pathological conditions, NETs are associated with severe tissue damage or certain auto-immune diseases. This review describes the recent progress made in the identification of the mechanisms involved in NETosis and discusses its interplay with autophagy and apoptosis.     

拟南芥生长素受体基因TIR1启动子的克隆及序列分析

以野生型拟南芥 (Arabidopsis Columbia)基因组DNA为模板,通过PCR扩增得到拟南芥生长素受体基因TIR1启动子2008片段,将该片断克隆到PGM-T载体上.序列分析表明,该启动子大小为2008bp,RNA聚合酶识别序列TATA-box,TIR1特异表达和增强序列CAAT-box皆完整,与已报道的序列比较仅有3个核苷酸发生改变,同源性为99.85%.将该启动子与GUS基因融合,构建成表达载体后,在拟南芥和烟草叶片中做瞬时表达,结果分析显示:拟南芥和烟草叶片中均有GUS 酶活性存在.     

拟南芥生长素受体基因TIR1启动子的初步分析

以野生型拟南芥（Arabidopsis Columbia）基因组DNA为模板,通过PCR扩增得到拟南芥生长素受体基因T1R1启动子的5个不同长度的系列缺失片段,将这些片断分别克隆到PGM—T载体上。序列分析表明,该启动子系列缺失片段的大小分别为2008bp、1524bp、939bp、532bp和321bp。与已报道的序列完全相同。将不同长度的启动子克隆片断分别与GUS基因融合,构建成表达载体后,在烟草叶片中作遗传转化。分析结果显示：不同长度的启动子片段已整合到烟草基因组中并有GUS酶活性存在,且不同长度启动子片段的表达活性有较明显差异。     

Lipid domains in bacterial membranes and the action of antimicrobial agents

There has been increasing interest in recent years in describing the lateral organization of membranes and the formation of membrane domains. Much of the focus in this area has been on the formation of cholesterol-rich domains in mammalian membranes. However, it is likely that there are domains in all biological membranes. One of the challenges has been to define the chemical composition, lifetime and size of these domains. There is evidence that bacteria have domains that are enriched in cardiolipin. In addition, the formation of lipid domains can be induced in bacteria by clustering negatively charged lipids with polycationic substances. Many antimicrobial compounds have multiple positive charges. Such polycationic compounds can sequester anionic lipids to induce lipid phase separation. The molecular interactions among lipids and their lateral packing density will be different in a domain from its environment. This will lead to phase boundary defects that will lower the permeability barrier between the cell and its surroundings. The formation of these clusters of anionic lipids may also alter the stability or composition of existing membrane domains that may affect bacterial function. Interestingly many antimicrobial agents are polycationic and therefore likely have some effect in promoting lipid phase segregation between anionic and zwitterionic lipids. However, this mechanism is expected to be most important for substances with sequential positive charges contained within a flexible molecule that can adapt to the arrangement of charged groups on the surface of the bacterial cell. When this mechanism is dominant it can allow the prediction of the bacterial species that will be most affected by the agent as a consequence of the nature of the lipid composition of the bacterial membrane.