Protein composition and biochemical characterization of venom from Sonoran Coral Snakes (Micruroides euryxanthus).

The elapid genus, Micruroides, is considered the sister clade of all New World coral snakes (Genus Micrurus), is monotypic, and is represented by Sonoran Coral Snakes, Micruroides euryxanthus. Coral snakes of the genus Micrurus have been reported to have venoms that are predominantly composed of phospholipases A2 (PLA2) or three finger toxins (3FTx), but the venoms of the genus Micruroides are almost completely unstudied. Here, we present the first description of the venom of M. euryxanthus including identification of some proteins as well as transcriptomic, and biological activity assays. The most abundant components within M. euryxanthus venom are 3FTxs (62.3%) and there was relatively low proportion of PLA2s (14.2%). The venom phenotype supports the hypothesis that the common ancestor of Micrurus and Micruroides had a 3FTx-dominated venom. Within the venom, there were two nearly identical α-neurotoxins (α-Ntx), one of which was designated Eurytoxin, that account for approximately 60% of the venom's lethality to mice. Eurytoxin was cloned, expressed in a soluble and active form, and used to produce rabbit hyperimmune serum. This allowed the analysis of its immunochemical properties, showing them to be different from the recombinant αNTx D.H., present in the venoms of some species of Micrurus. Finally, we observed that the commercial antivenom produced in Mexico for coral snake envenomation is unable to neutralize the lethality from M. euryxanthus venom. This work allowed the classification of Micruroides venom into the 3FTx-predominant group and identified the main components responsible for toxicity to mice.

Effects of feeding and digestion on myocardial contractility and expression of calcium-handling proteins in Burmese pythons (Python molurus).

Pythons are important models of studies on postprandial metabolism because their physiological responses are exacerbated when digesting large prey. Prior studies of these animals have shown hypertrophy of the cardiac tissue 2 to 3 days after feeding, coinciding with the peak of the specific dynamic action (SDA), but the consequences of this remodeling in myocardial contractility have not been studied, which is the purpose of this work. Specimens of Python molurus were divided into two groups: a Digesting group (2 days after feeding, at the peak of SDA), and a Fasting group (28 days after feeding). When compared to the Fasting group, the Digesting group showed higher relative ventricular mass and calcium-handling protein expression such as sarcoplasmic reticulum Ca2+-ATPase (SERCA), phospholamban (PLB), and the Na+/Ca2+ exchanger (NCX). Digesting pythons also exhibited significant increases in the cardiac contraction force (Fc), rates of force development and relaxation, and cardiac pumping capacity. Therefore, the higher SERCA, PLB and NCX expression levels increased cytosolic Ca2+ transient amplitude, improving myofilament force. These changes are crucial to maintain cardiac output and a relatively high and continuous blood flow required by metabolic expenditure that occurs in postprandial animals.

Expression of specific corneous beta proteins in the developing digits of the Japanese gecko (Gekko japonicus) reveals their role in the growth of adhesive setae.

Geckos possess strong adhesion ability, even can climb on smooth surface. Previous studies have shown that the setae of geckos play a crucial role in their ability to climb on vertical walls. But the biological molecular mechanism of their adhesion ability remains unclear. In the present study, the expression patterns of corneous beta proteins (CBPs) genes related to claws, scales, and feathers development (named as ge-gprp-9, ge-gprp-10, ge-gprp-11, ge-gprp-12, ge-gprp-13, ge-gprp-14, ge-gprp-15, and ge-gprp-16 respectively) in the developing pad lamellae of different embryonic stages (stage 34, stage 36, stage 39, and stage 42) of the Japanese gecko Gekko japonicus were detected using fluorescence quantitative PCR approach. The results showed that there were significant up-regulated expression of CBPs mRNA at embryonic stage 39 with the embryonic continuous maturation and the highest expression level was detected at embryonic stage 39 or stage 42. Moreover, the expression levels of four CBPs genes ge-gprp-9, ge-gprp-10, ge-gprp-11, and ge-gprp-12 in the embryonic and adult development of gecko were detected by fluorescence in situ hybridization technique. The results from in situ hybridization detection revealed that the positive signals of these CBPs genes expression were the same in the developing pad lamellae of G. japonicus. The positive signals of eight CBPs genes were mainly found in the setae tissue, oberhautchen, and ß layer, which suggests these CBPs genes are involved in the growth of setae.

Molecular cloning of ESR1, BMPR1B, and FOXL2 and differential expressions depend on maternal age and size during breeding season in cultured Asian yellow pond turtle (Mauremys mutica).

The reproductive capacity (egg size and egg number) of most of oviparous animals, including the Asian yellow pond turtle (Mauremys mutica), is constrained by the maternal age and body size, but the mechanism determining the maternal reproductive ability remains unclear. To disclose how maternal age and size affect reproductive ability of M. mutica, we first identified the full-length cDNAs from estrogen receptor 1 (ESR1), bone morphogenetic protein receptor 1B (BMPR1B), and forkhead box L2 (FOXL2). The ESR1 open reading frame (ORF) was 1, 767 bp encoding 588 amino acids. For BMPR1B, the ORF was 1599 bp encoding 532 amino acids, and an ORF of 906 bp encoding 301 amino acids was identified in FOXL2. The effects of maternal age and size on the expression of ESR1, BMPR1B, and FOXL2 in the ovary, brain, and uterus showed that ESR1 expression in large females was significantly lower than that in small females in the brain, but body size did not affect ESR1 expression in the ovary. The expression of ESR1 was significantly different in the different age groups and size groups, and there was interaction detected between maternal age and body size. However, BMPR1B expression in the ovary, brain, and uterus was independent of maternal age and size. In addition, we found different FOXL2 expression patterns between the brain and uterus, while detected interaction of female age and size in the brain and ovary. Our results imply the complexity and diversity of maternal age and size in regulating the expression of genes related to reproduction. These results provide more information for the maternal effects on the reproduction-related gene expression.

The Harderian gland transcriptomes of Caraiba andreae, Cubophis cantherigerus and Tretanorhinus variabilis, three colubroid snakes from Cuba.

The Harderian gland is a cephalic structure, widely distributed among vertebrates. In snakes, the Harderian gland is anatomically connected to the vomeronasal organ via the nasolacrimal duct, and in some species can be larger than the eyes. The function of the Harderian gland remains elusive, but it has been proposed to play a role in the production of saliva, pheromones, thermoregulatory lipids and growth factors, among others. Here, we have profiled the transcriptomes of the Harderian glands of three non-front-fanged colubroid snakes from Cuba: Caraiba andreae (Cuban Lesser Racer); Cubophis cantherigerus (Cuban Racer); and Tretanorhinus variabilis (Caribbean Water Snake), using Illumina HiSeq2000 100 bp paired-end. In addition to ribosomal and non-characterized proteins, the most abundant transcripts encode putative transport/binding, lipocalin/lipocalin-like, and bactericidal/permeability-increasing-like proteins. Transcripts coding for putative canonical toxins described in venomous snakes were also identified. This transcriptional profile suggests a more complex function than previously recognized for this enigmatic organ.

The effect of high fat diet on daily rhythm of the core clock genes and muscle functional genes in the skeletal muscle of Chinese soft-shelled turtle (Trionyx sinensis).

In the present study, we sought to investigate the influence of high fat diet on the core clock genes and the muscle functional genes daily expression in the skeletal muscle of Chinese soft-shelled turtle. The turtles were fed by two diets including a control fat diet (the CON treatment, 7.98% lipid) and a high fat diet (the HFD treatment, 13.86% lipid) for six weeks and administrated by the photophase regimen of 24h light/dark (12L:12D) cycle. After the feeding trial experiment, we measured the daily expression levels of 17 core clock genes (Clock, Bmal1/2, NPAS2, Tim, Cry1/2, Per1/2, DBP, AANAT, NIFL3, BHLHE40, NR1D2, RORA, RORB, RORC) and 12 muscle functional genes (FBXO32, MBNL1, MSTN, Myf5, Myf6, MyoD, MyoG, MyoM1, PPARa, PDK4, Trim63, UCP3) in the skeletal muscle of the two treatments. The results showed that except for Bmal1, NPAS2, Per2 and RORB, the expression of the other 13 core clock genes exhibited circadian oscillation in the CON treatment. Among the 12 muscle functional genes, MBNL1, PDK4 and MyoM1 did not exhibit circadian oscillation in the CON treatment. In the HFD treatment, the circadian rhythms expressional patterns of the 8 core clock genes (Clock, Bmal2, Cry2, Per1, DBP, NFIL3, BHLHE40 and RORA) and 6 muscle functional genes (MSTN, Myf5, MyoD, MyoG, PPARa and Trim63) were disrupted. In addition, compared with the CON treatment, the circadian expression of the 5 core clock genes (Tim, Cry1, AANAT, NR1D2, RORC) and the 3 muscle functional genes (FBXO32, Myf6, UCP3) showed the advanced or delayed expression peaks in the HFD treatment. In CON treatment, the circadian expression of the MyoG, MyoD, Myf6, FBXO32 and PPARa showed positive or negative correlation with the transcription pattern of Clock, Bmal2, Cry1/2, Per1/2. However, only the FBXO32 and Myf6 presented positive or negative correlation with the circadian expression of Cry1, RORB, AANAT and Tim in HFD treatment. In summary, these results demonstrate that the disruption of the circadian rhythm of the core clock genes and muscle functional genes in the skeletal muscle is closely associated with feeding high fat diet to Chinese soft-shelled turtle.

Transition from embryonic to adult epidermis in reptiles occurs by the production of corneous beta-proteins.

The adaptation of the epidermis in amniote vertebrates to life on land took place by a drastic change from an embryonic epidermis made of two-four periderm layers to a terrestrial-proof epidermis. This transition occurred by the increase in types and number of specialized corneous proteins coded by genes of the Epidermal Differentiation Complex. The prevalent types of corneous proteins produced in the reptilian epidermis contain a beta-sheet region of high amino acid homology which allows their polymerization into a meshwork of filaments forming the hard corneous material of scales and claws. The present immunogold ultrastructural study shows that this transition occurs with the synthesis of glycine-rich corneous beta-proteins (formerly indicated as beta-keratins) that are added to the initial framework of acidic intermediate filaments produced in the embryonic epidermis of lizards, snake, alligator and turtle. These corneous beta-proteins are accumulated in the transitional and definitive layers of reptilian epidermis formed underneath the transitory two-four layered embryonic epidermis. In the more specialized reptiles capable of shedding the epidermis as a single unit, such as lizards and snakes, special glycine-cysteine rich beta-proteins are initially produced in a single layer immediately formed beneath the embryonic epidermis, the oberhautchen. The latter layer allows the in ovo shedding of the embryonic epidermis in preparation for hatching, and in the following shedding cycles of the adult epidermis. The production of specialized corneous-specific beta-proteins in addition to intermediate filament keratins was probably an essential addition for terrestrial life during the evolution of reptiles into different lineages, including birds. The increase of glycine and cysteine in epidermal proteins enhanced the hydrophobicity, insolubility and mechanical strength of the stratum corneum in these amniotes.

Molecular cloning, recombinant expression and antibacterial activity analysis of hepcidin from Simensis crocodile (Crocodylus siamensis).

Hepcidin, a cysteine-rich cationic antibacterial peptide, plays an important role in human defense against pathogen infection. However, its role in reptile immune response and whether it is involved in antibacterial immune have not yet been proven. In order to study the antibacterial activity of Crocodylus siamensis hepcidin (Cshepc), a common reptile which lives in topic region of Southeast Asia, a cDNA sequence of Cshepc was cloned, which included an open reading frame (ORF) of 300 bp encoding a 99 amino acid preprohepcidin. Cshepc has eight cysteines formed four conserved disulfide bridges, similarly to that of human's. Sequence analysis showed that Cshepc mature peptide was more conserved than that of preprohepcidin. Tissue expression analysis indicated that Cshepc transcripts were highly expressed in the liver, muscle and heart of C. siamensis. Recombinant expressed hepcidin could significantly inhibit the growth of the Gram-negative bacteria Escherichia coli and Aeromonas sobria as well as the Gram-positive bacterium Staphylococcus aureus, and Bacillus subtilis in vitro, suggesting that Cshepc, like human hepcidin could play a role in the antibacterial function in hosts innate immune response.

Soluble expression and one-step purification of a neurotoxin Huwentoxin-I in Escherichia coli.

Huwentoxin-I (HWTX-I) is a small 33-amino acid neurotoxin from the venom of the Chinese bird spider Ornithoctonus huwena. HWTX-I selectively blocks N-type voltage-sensitive calcium channels (N-VSCCs) and has great potential for clinical application as a novel analgesic without inducing drug tolerance. However, there are still many unsolved issues for this peptide, such as its clinical efficacy in analgesia, anesthesia, and even its potential role in drug rehabilitation. Therefore, large amounts of active recombinant HWTX-I are urgently needed. In this report, we describe a novel and efficient way to produce large amounts of the valuable form in Escherichia coli. HWTX-I was expressed in soluble form as an N-terminal intein fusion product. After affinity purification, a pH shift-induced self-cleavage of the intein released HWTX-I, resulting in a single-column purification of the target protein. The whole-cell patch clamp assay showed that purified HWTX-I has activity similar to another commercialized N-VSCC blocker omega-conotoxin MVIIA. Production of HWTX-I by this method has the major advantages of high efficiency and low cost.

Snake venomics of Central American pitvipers: clues for rationalizing the distinct envenomation profiles of Atropoides nummifer and Atropoides picadoi.

We report the proteomic characterization of the Central American pitvipers Atropoides nummifer and Atropoides picadoi. The crude venoms were fractionated by reverse-phase high-performance liquid chromatography (HPLC), followed by analysis of each chromatographic fraction by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), N-terminal sequencing, matrix-assisted laser desorption ionization-time of flight (MALDI-TOF) mass fingerprinting, and collision-induced dissociation-tandem mass spectrometry (CID-MS/MS) of tryptic peptides. Each venom contained a number of bradykinin-potentiating peptides and around 25-27 proteins of molecular masses in the range of 7-112 kDa, belonging to only nine different toxin families (disintegrin, DC fragment, snake venom vascular endothelial growth factor, phospholipases A2, serine protease, cysteine-rich secretory proteins, C-type lectins, L-amino acid oxidase, and Zn2+-dependent metalloproteases), albeit distinctly distributed among the two Atropoides species. In addition, A. nummifer expresses low amounts of a three-finger toxin not detected in the venom of A. picadoi. The major toxins of A. nummifer belong to the PLA2 (relative abundance, 36.5%) and the serine proteinase (22%) families, whereas the most abundant A. picadoi toxins are Zn2+-dependent metalloproteinases (66.4%). We estimate that the similarity of venom proteins between the two Atropoides taxa may be around 14-16%. The high degree of differentiation in the venom proteome among congeneric taxa emphasizes unique aspects of venom composition of related species of Atropoides snakes and points to a strong role for adaptive diversification via natural selection as a cause of this distinctiveness. On the other hand, their distinct venom toxin compositions provide clues for rationalizing the low hemorrhagic, coagulant, and defibrinating activities and the high myotoxic and proteolytic effects evoked by A. nummifer snakebite in comparison to other crotaline snake venoms and the high hemorrhagic activity of A. picadoi.

[The analysis of heterogeneity of HWTX-I expressed in Pichia pastoris].

To seek the reason of heterogeneity of recombinant HWTX-I (rHWTX-I) expressed in Pichia pastoris. We expressed HWTX-I gene of interest in Pichia pastoris GS115/HWTX-I. The heterogenous product expressed was separated, purified and identified by using Ion exchange HPLC, reverse HPLC, Tricine SDS-PAGE and MALDI-TOF Mass Spectrometry and then sequenced in both N-terminus and C-terminus. These results show that the heterogeneity of rHWTX-I results from the incomplete processing of signal peptide of N-terminus and the internal degradation of C-terminus. Biological activity assay shows that the activity of the heterogenous rHWTX-I only showed 30% activity compared with the native HWTX-I. The Solutions to how to avoid the heterogeneity are also discussed.

High affinity copper transport protein in the lizard Podarcis sicula: molecular cloning, functional characterization and expression in somatic tissues, follicular oocytes and eggs.

Copper (Cu) is an essential element required in many biological processes including cellular growth and development. The molecular mechanisms involved in copper homeostasis include proteins that play a role in Cu uptake. Genes encoding high affinity copper transporters (Ctr) have been identified in yeast, plant and mammalian cells. Analysis of copper and zinc content in growing ovarian follicles and ovulated eggs of the reptilian Podarcis sicula demonstrated that the levels of both metals rise during oocyte growth, reaching the maximum in ovulated eggs. By exploiting the remarkable evolutionary conservation of the primary structure of Ctr proteins, cDNA encoding a Ctr was isolated from the liver of the lizard P. sicula by reverse transcriptase PCR and RACE strategy by using primers designed based on consensus motifs present in mammalian Ctr. The predicted protein sequence contains three transmembrane domains and a putative hydrophilic extracellular amino-terminal domain. Besides complementing the respiratory deficiency of yeast cells defective in high affinity Cu transport, expression of lizard Ctr1(1) in Hek293 cells stimulates Cu uptake.Gene expression assessed by Northern blot hybridization of RNA from different tissues of P. sicula shows the highest levels of transcript in both intestine and liver. The profile of Ctr1 mRNA in growing ovarian follicles and eggs demonstrates that the transcript accumulates during the oocyte growth and reaches the highest levels in ovulated eggs. These results suggest that lizard Ctr1 protein may function in Cu acquisition in growing oocytes and eggs.

Molecular cloning and expression of a functional snake venom vascular endothelium growth factor (VEGF) from the Bothrops insularis pit viper. A new member of the VEGF family of proteins.

During the generation of abundant expressed sequence tags from the Viperidae snake Bothrops insularis venom glands, we identified for the first time a cDNA coding for a putative vascular endothelial growth factor-like (VEGF-like) protein. The deduced primary sequence, after complete sequencing of the longest snake venom VEGF (svVEGF) cDNA, displayed similarity with vertebrate VEGFs and with the hypotensive factor from Vipera aspis venom. Its cDNA was subcloned, expressed in Escherichia coli with a His(6) tag as an insoluble monomer, and purified by Ni(2+)-affinity chromatography after 8 m urea extraction. Antiserum against svVEGF was generated and tested in Western blot against proteins from snake venoms and cellular extracts. The mature svVEGF appears to be ubiquitously distributed throughout snake venoms and was also confirmed by Northern blot studies of other related Viperidae species and by cDNA cloning of svVEGF from Bothrops jararaca pit viper. The produced recombinant protein dimerizes after refolding processes and was biologically characterized, showing ability to increase vascular permeability. These results established that svVEGF is a novel and important active toxin during the early stages of bothropic snake bite envenoming and represents a new member of the VEGF family of proteins.