A nesting of vipers: Phylogeny and historical biogeography of the Viperidae (Squamata: Serpentes)

Despite their medical interest, the phylogeny of the snake family Viperidae remains inadequately understood. Previous studies have generally focused either on the pitvipers (Crotalinae) or on the Old World vipers (Viperinae), but there has been no comprehensive molecular study of the Viperidae as a whole, leaving the affinities of key taxa unresolved. Here, we infer the phylogenetic relationships among the extant genera of the Viperidae from the sequences of four mitochondrial genes (cytochrome b, NADH subunit 4, 16S and 12S rRNA). The results confirm Azemiops as the sister group of the Crotalinae, whereas Causus is nested within the Viperinae, and thus not a basal viperid or viperine. Relationships among the major clades of Viperinae remain poorly resolved despite increased sequence information compared to previous studies. Bayesian molecular dating in conjunction with dispersal-vicariance analysis suggests an early Tertiary origin in Asia for the crown group Viperidae, and rejects suggestions of a relatively recent, early to mid-Tertiary origin of the Caenophidia.     

Venom peptide analysis of Vipera ammodytes meridionalis (Viperinae) and Bothrops jararacussu (Crotalinae) demonstrates subfamily-specificity of the peptidome in the family Viperidae

Snake venom peptidomes are valuable sources of pharmacologically active compounds. We analyzed the peptidic fractions (peptides with molecular masses < 10,000 Da) of venoms of Vipera ammodytes meridionalis (Viperinae), the most toxic snake in Europe, and Bothrops jararacussu (Crotalinae), an extremely poisonous snake of South America. Liquid chromatography/mass spectrometry (LC/MS), direct infusion electrospray mass spectrometry (ESI-MS) and matrix-assisted desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS) were applied to characterize the peptides of both snake venoms. 32 bradykinin-potentiating peptides (BPPs) were identified in the Crotalinae venom and their sequences determined. 3 metalloproteinase inhibitors, 10 BPPs and a Kunitz-type inhibitor were observed in the Viperinae venom peptidome. Variability in the C-terminus of homologous BPPs was observed, which can influence the pharmacological effects. The data obtained so far show a subfamily specificity of the venom peptidome in the Viperidae family: BPPs are the major peptide component of the Crotalinae venom peptidome lacking Kunitz-type inhibitors (with one exception) while the Viperinae venom, in addition to BPPs, can contain peptides of the bovine pancreatic trypsin inhibitor family. We found indications for a post-translational phosphorylation of serine residues in Bothrops jararacussu venom BPP (S[combining low line]QGLPPGPPIP), which could be a regulatory mechanism in their interactions with ACE, and might influence the hypotensive effect. Homology between venom BPPs from Viperidae snakes and venom natriuretic peptide precursors from Elapidae snakes suggests a structural similarity between the respective peptides from the peptidomes of both snake families. The results demonstrate that the venoms of both snakes are rich sources of peptides influencing important physiological systems such as blood pressure regulation and hemostasis. The data can be used for pharmacological and medical applications.     

Defensive and infrared reception responses of true vipers, pitvipers, Azemiops and colubrids

It has been suggested that true vipers (Viperidae: Viperinae) possess the ability to detect temperature differences between objects despite the lack of an apparent infrared radiation sensor. We tested the ability to distinguish between heated and unheated targets in three species of pitvipers (Viperidae: Crotalinae), four species of true vipers, two species of colubrids (Colubridae: Natricinae, Colubrinae) and Azemiops feae (Viperidae: Azemiopinae). All species of pitvipers tested could distinguish between the warm and cool targets, while no tested species of true viper, colubrid or Azemiops demonstrated this ability. In addition, pitvipers exhibited behaviors that true vipers or Azemiops did not exhibit. Our results suggest that the tested species of true vipers, Azemiops and colubrids may not posses the ability to sense infrared radiation or do not use it in a defensive context, and suggest that some defensive behaviors are associated with the pit organ in pitvipers.     

蝰科(Viperidae)蝮亚科(Crotalinae)线粒体12S rRBA基因序列分析及其系统发育

对蝮亚科（蛇岛蝮Ｇｌｏｙｄｉｕｓ ｓｈｅｄａｏｅｎｓｉｓ Ｚｈａｏ、黑眉蝮Ｇｌｏｙｄｉｕｓ ｓａｘａｔｉｌｉｓ Ｅｍｅｌｉａｎｏｖ、乌苏 里蝮Ｇｌｏｙｄｉｕｓ ｕｓｓｕｒｒｉｅｎｓｉｓ　 Ｅｍｅｌｉａｎｏｖ、　竹叶青Ｔｒｉｍｅｒｅｓｕｒｕｓ 　ｓｔｅｊｎｅｇｅｒｉ 　Ｓｃｈｍｉｄｔ和分别来自不 同地区的尖吻蝮Ｄｅｉｎａｇｋｉｓｔｒｏｄｏｎ　ａｃｕｔｕｓ　Ｇｕｅｎｔｈｅｒ、短尾蝮Ｇｌｏｙｄｉｕｓ　ｂｒｅｖｉｃａｕｄｕｓ　Ｓｔｅｊｎｅｇｅｒ各 两条）６种蛇共８个个体测定、分析了约３７０ｂｐ线粒体１２Ｓ ｒＲＮＡ基因序列;以游蛇科链蛇属半 棱鳞链蛇Ｄｉｎｏｄｏｎ ｓｅｍｉｃａｒｉｎａｔｕｓ　序列为外群构建分子系统树。分子数据结果支持尖吻蝮形态 学的属级分类地位;提示蛇岛蝮位于黑眉蝮的蛇岛亚种分类地位,同时探讨了蛇岛蝮的起源 问题;并提示短尾蝮和乌苏里蝮同位于种级分类地位。     

Exon-intron organization of TRGC genes in sheep

A series of genomic clones derived from a sheep library were used to determine the germline configuration and the exon-intron organization of TRGC2, TRGC3, and TRGC4 genes. Based on the outcomes of molecular analysis, we compared and aligned the genomic sequences with the known complete cDNA sequences of sheep and deduced the exon-intron organization of TRGC genes in this ruminant animal, EX1, corresponding to the disulfide-linked constant domain, and EX3, corresponding to the transmembrane and cytoplasmatic domains, are similar in length in all genes. Conversely, the hinge-encoding EX2A, EX2B, and EX2C exons differ in number and length between genes, and EX2A contains the TTKPP motif irrespective of whether it occurs in single or triplicate form. The molecular data also indicate that at least one additional gene is present in sheep. Phylogenetic analysis grouped the ruminant TRGC genes in two clusters that could have emerged from two ancestral forms that underwent a series of duplications giving rise to the new sequences that were selected and then fixed in the ruminant lineages. A correlation between the cluster distribution in the phylogenetic tree of TRGC genes and their expression during fetal development is discussed.     

Interaction of the neurotoxic and nontoxic secretory phospholipases A2 with the crotoxin inhibitor from Crotalus serum.

Crotalus durissus terrificus snakes possess a protein in their blood, named crotoxin inhibitor from Crotalus serum (CICS), which protects them against crotoxin, the main toxin of their venom. CICS neutralizes the lethal potency of crotoxin and inhibits its phospholipase A2 (PLA2) activity. The aim of the present study is to investigate the specificity of CICS towards snake venom neurotoxic PLA2s (beta-neurotoxins) and nontoxic mammalian PLA2s. This investigation shows that CICS does not affect the enzymatic activity of pancreatic and nonpancreatic PLA2s, bee venom PLA2 and Elapidae beta-neurotoxins but strongly inhibits the PLA2 activity of Viperidae beta-neurotoxins. Surface plasmon resonance and PAGE studies further demonstrated that CICS makes complexes with monomeric and multimeric Viperidae beta-neurotoxins but does not interact with nontoxic PLA2s. In the case of dimeric beta-neurotoxins from Viperidae venoms (crotoxin, Mojave toxin and CbICbII), which are made by the noncovalent association of a PLA2 with a nonenzymatic subunit, CICS does not react with the noncatalytic subunit, instead it binds tightly to the PLA2 subunit and induces the dissociation of the heterocomplex. In vitro assays performed with Torpedo synaptosomes showed a protective action of CICS against Viperidae beta-neurotoxins but not against other PLA2 neurotoxins, on primary and evoked liberation of acetylcholine. In conclusion, CICS is a specific PLA2 inhibitor of the beta-neurotoxins from the Viperidae family.     

Comparative study of the edema-inducing activity of snake venoms

1. The edema-inducing activity of 24 venoms from snakes of the subfamilies of Elapinae, Hydrophiini, Crotalinae and Viperinae was determined. 2. All snake venoms tested are very potent edema inducers. The minimum edema doses of the venoms ranged from 0.16 to 3.41 micrograms per mouse paw. 3. The venoms induced a rapid onset edema which peaked within 1 h of injection and declined thereafter; at low dose, however, some venoms induced a rapid onset edema that sustained over a longer duration.     

Tracing the evolution of H-2 D region genes using sequences associated with a repetitive element

The class I genes in the murine MHC are genetically divided into the K, D, Qa, and T1a region subfamilies. These genes presumably arose by duplication from a common class I ancestor. Oligonucleotide probes specific for sequences associated with a moderately repetitive B2 SINE element, which is inserted into the 3' untranslated region of the H-2D and H-2L genes, were used to examine the evolutionary relationship between these classically defined D region genes (H-2D and H-2L) and the other members of the class I gene family. Hybridization analyses of recombinant cosmid and genomic DNA indicated that the D region genes separated genetically from the other members of the class I gene family 12 to 14 million years ago. The evidence suggests that during this time frame the chromosomal segment harboring the characteristic insertion became fixed in the ancestral population which gave rise to Mus domesticus. Previous studies have shown that the number of genes present in the Qa and T1a regions varies among inbred strains and among laboratory stocks of wild mice derived from more distant species on the genus Mus. No evidence was found in this study to support the hypothesis that variation in class I gene number is the result of recent duplications of the functionally defined class I genes of the D region, H-2D and H-2L.     

Two Tandemly Arrayed Transfer-RNA-Derived SINEs of the Medaka (<Emphasis Type="BoldItalic">Oryzias latipes</Emphasis>)

: Two tandemly arrayed short interspersed repetitive element (SINE) sequences were found in medaka (Oryzias latipes). These two SINE sequences, designated SINE1 and SINE2, were flanked by a 180-bp AT-rich region. Both appeared to be derived from transfer RNA. The former exhibited 80% sequence homology to human tRNA^Ala and the latter exhibited 94% sequence homology to rat tRNA^Ser. SINE1 contained the retroviral U5 region, whereas SINE2 did not. This is the first sequence-level demonstration of the existence of neighboring SINEs in medaka.     

A novel class of SINE elements derived from 5S rRNA

Eukaryotic genomes are colonized by different retroposons, including short interspersed repetitive elements (SINEs). All currently known SINEs are derived from tRNA and 7SL RNA genes and exploit their type 2 internal pol III promoters. We report here a novel class of SINE elements, called SINE3, derived from 5S rRNA. SINE3s are transcribed from the type 1 internal pol III promoter. Approximately 10,000 copies of SINE3 elements are present in the zebrafish genome, they constitute approximately 0.4% of the genomic DNA. Some elements are as little as 1% diverged from each other, indicating that the retrotransposition of SINE3 in zebrafish is an ongoing process. The 3'-tail of SINE3 is significantly similar to that of CR1-like non-LTR retrotransposons, represented by numerous subfamilies in the zebrafish genome. Analogously to CR1-like elements, SINE3 copies are not flanked by target site duplications, and their 3' termini are composed of (ACATT)n and (ATT)n microsatellites, specific for different subfamilies of SINE3. Given the common structural features, it is highly likely that the enzymatic machinery encoded by CR1-like elements powers proliferation of SINE3.     

Structure and phylogeny of the venom group I phospholipase A(2) gene

Phospholipases A(2) (PLA(2)s) catalyzing the hydrolysis of phospholipids form a family of proteins with diverse physiological and pharmacological properties. While there have been several reports on the cloning of PLA(2) cDNAs, very few studies have been carried out on the PLA(2) genes and, most importantly, no information has been available on the gene structure and function of group I venom PLA(2). This study, on the PLA(2) gene from a spitting cobra, besides being the very first report on any venom group I PLA(2) gene, constitutes the missing link in the biology and evolution of phospholipases. The 4-kb gene consists of four exons and three introns and resembles the human pancreatic PLA(2) gene. However, the size of intron 3 in particular is much smaller than that in the pancreatic gene. Interestingly, the information for the toxic and most of the pharmacological properties of the venom PLA(2) can be attributed to the end of exon 3 and the whole of exon 4 of the gene. This functional delineation fits in well with the theory of adaptive evolution exhibited by the venom PLA(2)s. We also show that the mammalian pancreatic and elapid PLA(2)s have similar paths of evolution (probably following gene duplication) from a common ancestral gene. Venom group II phospholipases, although evolved from the same ancestor, diverged early in evolution from the group I PLA(2) genes. Intriguingly, CAT reporter gene assays and DNase 1 footprinting studies on the promoter and its deletion constructs using CHO and HepG2 cell lines identified the possible involvement of cis elements such as Sp1, AP2, gamma-IRE, and (TG)(12) repeats in the expression of the gene in a tissue-specific manner.     

Evolution of a multigene family of V kappa germ line genes

We have isolated a series of related V kappa germ line genes from a BALB/c sperm DNA library. DNA sequence analysis of four members of this V kappa 24 multigene family implies that three V kappa genes are functional whereas the fourth one (psi V kappa 24) is a pseudogene. The prototype gene (V kappa 24) encodes the variable region gene segment expressed in an immune response against phosphorylcholine. The other two functional genes (V kappa 24A and V kappa 24B) may be expressed against streptococcal group A carbohydrate. The time of divergence of the four genes was estimated by the rate of synonymous nucleotide changes. This implies that an ancestral gene has duplicated approximately 33-35 million years ago and a subsequent gene duplication event has occurred approximately 23 million years ago.     

Molecular phylogenetic relationships of pond frogs distributed in the Palearctic region inferred from DNA sequences of mitochondrial 12S ribosomal RNA and cytochrome b genes

The evolutionary relationships of pond frogs distributed in the Far East and Europe were investigated by analyses of nucleotide sequences of mitochondrial 12S ribosomal RNA (12S rRNA) and cytochrome b (cyt b) genes. The nucleotide sequences of a 412-bp segment of the 12S rRNA gene and a 534-bp segment of the cyt b gene were determined by the PCR-direct sequencing method using 19 frogs belonging to six species and one subspecies distributed in the Palearctic region. Phylogenetic trees were constructed by the neighbor-joining and maximum-likelihood methods using Rana catesbeiana or Xenopus laevis as an outgroup. The 412-bp segment of the 12S rRNA gene contained 65 variable sites including gap sites, and the 534-bp segment of the cyt b gene contained 160 variable sites. The nucleotide sequence divergences of the 12S rRNA gene were 0.25-4.83% within the Far Eastern frogs, 0.25-6.22% within the European frogs, and 8.74-11.24% between the Far Eastern and the European frogs, whereas those of the cyt b gene were 3.64-14.73% within the Far Eastern frogs, 0.38-14.42% within the European frogs, and 16.53-23.58% between the Far Eastern and the European frogs. Although most nucleotide substitutions were at the third codon position of the cyt b gene and were silent mutations, 4 amino acid replacements occurred within the Far Eastern frogs, 4 within the European frogs, and 11 between the Far Eastern and the European frogs. The phylogenetic trees constructed from the nucleotide sequence divergences showed slightly different topologies for the 12S rRNA and cyt b genes. R. esculenta from Ukraine was closely related to R. lessonae from Luxembourg in both the 12S rRNA and the cyt b gene sequences.     

Two regulatory fim genes, fimB and fimE, control the phase variation of type 1 fimbriae in Escherichia coli.

The expression of type 1 fimbriae in Escherichia coli is phase dependent, i.e. a cell is either completely fimbriated or bald. This phenomenon is due to the periodic inversion of a specific 300-bp DNA segment containing the promoter for the fimbrial subunit gene, fimA. The phase switch is controlled by the products of two regulatory genes, fimB and fimE, located upstream of fimA. The fimB and fimE proteins direct the phase switch into the 'on' and 'off' position, respectively. The DNA sequence of a 3000-bp region containing the two genes has been determined. The fimB and fimE proteins exhibit strong homology and have most likely originated by duplication of an ancestral gene. They are highly basic implying that they control the phase switch through interaction at the DNA level.     

Purification, characterization and cytokine release function of a novel Arg-49 phospholipase A(2) from the venom of Protobothrops mucrosquamatus

Group IIA phospholipase A(2) (PLA(2)) are major components in Viperidae/Crotalidae venom. In the present study, a novel PLA(2) named promutoxin with Arg at the site 49 has been purified from the venom of Protobothrops mucrosquamatus by chromatography. It consists of 122 amino acid residues with a molecular mass of 13,656 Da assessed by MALDI-TOF. It has the structural features of snake venom group IIA PLA(2)s, but has no PLA(2) enzymatic activity. Promutoxin shows higher amino acid sequence identity to the K49 PLA(2)s (72-95%) than to D49 PLA(2)s (52-58%). Promutoxin exhibits potent myotoxicity in the animal model with as little as 1 microg of promutoxin causing myonecrosis and myoedema in the gastrocnemius muscle of mice. Promutoxin is also able to stimulate the release of IL-12, TNFalpha, IL-6 and IL-1beta from human monocytes, and induce IL-2, TNFalpha and IL-6 release from T cells, indicating that this snake venom group IIA PLA(2) is actively involved in the inflammatory process in man caused by snake venom poisoning.     

Sequencing and expression of the second allele of the interleukin-1beta1 gene in rainbow trout (Oncorhynchus mykiss): identification of a novel SINE in the third intron

A lambda clone containing a rainbow trout IL-1beta1 gene was isolated by a PCR screening strategy from a genomic library cloned in lambda GEM-11, and an EcoRI fragment from this clone was fully sequenced, and contained 1680 bp 5'-flanking sequence, the whole IL-1beta1 gene open reading frame, and the 3'-flanking region with two potential poly A signals and poly A sites. This clone encoded a protein that shared 99.8% identity to the previously published trout IL-1beta1 cDNA sequence, with only three base substitutions. The main difference was that this clone had an additional complete HpaI SINE insertion in the 3rd intron making intron III 211 bp larger (834 bp via 623 bp). Thus this sequence was designated as allele B (Big intron III) of IL-1beta1 and the previously reported sequence as allele S (Short intron III). Three lines of evidence (allele specific PCR, cloning and sequencing, and direct sequencing of PCR products) revealed that allele B was constitutively expressed and could respond to stimulation with lipopolysaccharide or trout recombinant IL-1beta. Searching of the GenBank database with the HpaI SINE sequence resulted in three additional HpaI loci being identified in rainbow trout. Another SINE retroposition was also identified in the same intron of both alleles of IL-1beta1 by comparison with the trout IL-1beta2 gene. This novel SINE sequence, sharing high homology with the HpaI SINE at the 3'-end region, is present in EST databases of several species including human, mouse and fish. The consensus of this novel SINE shares 57 to 61% identities to tRNA-Leu from different species. Another older retroposition event in the same intron of IL-1beta1 has also been hypothesised, recognised as six adenines, that may function as a RNA polIII terminator. A model for the IL-1beta1 allele formation is proposed. Following the earliest retroposition into one of the two IL-1beta genes that resulted from a genome duplication in salmonids, the proper environment for successive PV SINE retroposition was created. A recent retroposition of the HpaI SINE in IL-1beta1 resulted in the formation of the two alleles of IL-1beta1. Examination of the SINEs insertion and their host gene microenvironments revealed that the SINE retroposition does not appear random, both in the site selection and the direction of insertion. The mechanism governing this outcome is discussed.