Your search keyword '"Undheim, Eivind A. B."' showing total 7 results

1. Molecular Phylogeny and Evolution of the Proteins Encoded by Coleoid (Cuttlefish, Octopus, and Squid) Posterior Venom Glands

Author

Ruder, Tim, Sunagar, Kartik, Undheim, Eivind A. B., Ali, Syed A., Wai, Tak-Cheung, Low, Dolyce H. W., Jackson, Timothy N. W., King, Glenn F., Antunes, Agostinho, and Fry, Bryan G.

Published

2013

2. Structural and Molecular Diversification of the Anguimorpha Lizard Mandibular Venom Gland System in the Arboreal Species Abronia graminea

Author

Koludarov, Ivan, Sunagar, Kartik, Undheim, Eivind A. B., Jackson, Timothy N. W., Ruder, Tim, Whitehead, Darryl, Saucedo, Alejandro C., Mora, G. Roberto, Alagon, Alejandro C., King, Glenn, Antunes, Agostinho, and Fry, Bryan G.

Published

2012

3. Toxin structures as evolutionary tools: Using conserved 3D folds to study the evolution of rapidly evolving peptides.

Author

Undheim, Eivind A. B., Mobli, Mehdi, and King, Glenn F.

Subjects

*PEPTIDES, *TOXINS, *THREE-dimensional imaging, *MOLECULAR evolution, *HYPOTHESIS

Abstract

Three-dimensional (3D) structures have been used to explore the evolution of proteins for decades, yet they have rarely been utilized to study the molecular evolution of peptides. Here, we highlight areas in which 3D structures can be particularly useful for studying the molecular evolution of peptide toxins. Although we focus our discussion on animal toxins, including one of the most widespread disulfide-rich peptide folds known, the inhibitor cystine knot, our conclusions should be widely applicable to studies of the evolution of disulfide-constrained peptides. We show that conserved 3D folds can be used to identify evolutionary links and test hypotheses regarding the evolutionary origin of peptides with extremely low sequence identity; construct accurate multiple sequence alignments; and better understand the evolutionary forces that drive the molecular evolution of peptides. Also watch the [ABSTRACT FROM AUTHOR]

Published

2016

4. Diversification of a single ancestral gene into a successful toxin superfamily in highly venomous Australian funnel-web spiders.

Author

Pineda, Sandy S., Sollod, Brianna L., Wilson, David, Darling, Aaron, Sunagar, Kartik, Undheim, Eivind A. B., Kely, Laurence, Antunes, Agostinho, Fry, Bryan G., and King, Glenn F.

Subjects

SPIDER venom, AGELENIDAE, BIODIVERSITY, NATURAL selection, PEPTIDES, ION channels, TOXIN receptors

Abstract

Background Spiders have evolved pharmacologically complex venoms that serve to rapidly subdue prey and deter predators. The major toxic factors in most spider venoms are small, disulfide-rich peptides. While there is abundant evidence that snake venoms evolved by recruitment of genes encoding normal body proteins followed by extensive gene duplication accompanied by explosive structural and functional diversification, the evolutionary trajectory of spidervenom peptides is less clear. Results Here we present evidence of a spider-toxin superfamily encoding a high degree of sequence and functional diversity that has evolved via accelerated duplication and diversification of a single ancestral gene. The peptides within this toxin superfamily are translated as prepropeptides that are posttranslationally processed to yield the mature toxin. The Nterminal signal sequence, as well as the protease recognition site at the junction of the propeptide and mature toxin are conserved, whereas the remainder of the propeptide and mature toxin sequences are variable. All toxin transcripts within this superfamily exhibit a striking cysteine codon bias. We show that different pharmacological classes of toxins within this peptide superfamily evolved under different evolutionary selection pressures. Conclusions Overall, this study reinforces the hypothesis that spiders use a combinatorial peptide library strategy to evolve a complex cocktail of peptide toxins that target neuronal receptors and ion channels in prey and predators. We show that the ω-hexatoxins that target insect voltagegated calcium channels evolved under the influence of positive Darwinian selection in an episodic fashion, whereas the κ-hexatoxins that target insect calcium-activated potassium channels appear to be under negative selection. A majority of the diversifying sites in the ω- hexatoxins are concentrated on the molecular surface of the toxins, thereby facilitating neofunctionalisation leading to new toxin pharmacology. [ABSTRACT FROM AUTHOR]

Published

2014

5. Venom Down Under: Dynamic Evolution of Australian Elapid Snake Toxins.

Author

Jackson, Timothy N. W., Sunagar, Kartik, Undheim, Eivind A. B., Koludarov, Ivan, Chan, Angelo H. C., Sanders, Kate, Ali, Syed A., Hendrikx, Iwan, Dunstan, Nathan, and Fry, Bryan G.

Subjects

ELAPIDAE, SNAKE venom, TOXINS, PHYLOGENY, PROTEINS

Abstract

Despite the unparalleled diversity of venomous snakes in Australia, research has concentrated on a handful of medically significant species and even of these very few toxins have been fully sequenced. In this study, venom gland transcriptomes were sequenced from eleven species of small Australian elapid snakes, from eleven genera, spanning a broad phylogenetic range. The particularly large number of sequences obtained for three-finger toxin (3FTx) peptides allowed for robust reconstructions of their dynamic molecular evolutionary histories. We demonstrated that each species preferentially favoured different types of α-neurotoxic 3FTx, probably as a result of differing feeding ecologies. The three forms of α-neurotoxin [Type I (also known as (aka): short-chain), Type II (aka: long-chain) and Type III] not only adopted differential rates of evolution, but have also conserved a diversity of residues, presumably to potentiate prey-specific toxicity. Despite these differences, the different α-neurotoxin types were shown to accumulate mutations in similar regions of the protein, largely in the loops and structurally unimportant regions, highlighting the significant role of focal mutagenesis. We theorize that this phenomenon not only affects toxin potency or specificity, but also generates necessary variation for preventing/delaying prey animals from acquiring venom-resistance. This study also recovered the first full-length sequences for multimeric phospholipase A2 (PLA2) 'taipoxin/paradoxin' subunits from non-Oxyuranus species, confirming the early recruitment of this extremely potent neurotoxin complex to the venom arsenal of Australian elapid snakes. We also recovered the first natriuretic peptides from an elapid that lack the derived C-terminal tail and resemble the plesiotypic form (ancestral character state) found in viper venoms. This provides supporting evidence for a single early recruitment of natriuretic peptides into snake venoms. Novel forms of kunitz and waprin peptides were recovered, including dual domain kunitz-kunitz precursors and the first kunitz-waprin hybrid precursors from elapid snakes. The novel sequences recovered in this study reveal that the huge diversity of unstudied venomous Australian snakes are of considerable interest not only for the investigation of venom and whole organism evolution but also represent an untapped bioresource in the search for novel compounds for use in drug design and development. [ABSTRACT FROM AUTHOR]

Published

2013

6. The Diversity of Venom: The Importance of Behavior and Venom System Morphology in Understanding Its Ecology and Evolution.

Author

Schendel, Vanessa, Rash, Lachlan D., Jenner, Ronald A., and Undheim, Eivind A. B.

Subjects

VENOM, PHARMACOLOGY, ANIMAL diversity, ECOLOGY, MOLECULAR evolution, MORPHOLOGY, KNOWLEDGE gap theory

Abstract

Venoms are one of the most convergent of animal traits known, and encompass a much greater taxonomic and functional diversity than is commonly appreciated. This knowledge gap limits the potential of venom as a model trait in evolutionary biology. Here, we summarize the taxonomic and functional diversity of animal venoms and relate this to what is known about venom system morphology, venom modulation, and venom pharmacology, with the aim of drawing attention to the importance of these largely neglected aspects of venom research. We find that animals have evolved venoms at least 101 independent times and that venoms play at least 11 distinct ecological roles in addition to predation, defense, and feeding. Comparisons of different venom systems suggest that morphology strongly influences how venoms achieve these functions, and hence is an important consideration for understanding the molecular evolution of venoms and their toxins. Our findings also highlight the need for more holistic studies of venom systems and the toxins they contain. Greater knowledge of behavior, morphology, and ecologically relevant toxin pharmacology will improve our understanding of the evolution of venoms and their toxins, and likely facilitate exploration of their potential as sources of molecular tools and therapeutic and agrochemical lead compounds. [ABSTRACT FROM AUTHOR]

Published

2019

7. Molecular Evolution of Vertebrate Neurotrophins: Co-Option of the Highly Conserved Nerve Growth Factor Gene into the Advanced Snake Venom Arsenalf.

Author

Sunagar, Kartik, Fry, Bryan Grieg, Jackson, Timothy N. W., Casewell, Nicholas R., Undheim, Eivind A. B., Vidal, Nicolas, Ali, Syed A., King, Glenn F., Vasudevan, Karthikeyan, Vasconcelos, Vitor, and Antunes, Agostinho

Subjects

MOLECULAR evolution, VERTEBRATES, NEUROTROPHINS, NERVE growth factor, SNAKE venom, PROTEIN structure, NEUROPLASTICITY

Abstract

Neurotrophins are a diverse class of structurally related proteins, essential for neuronal development, survival, plasticity and regeneration. They are characterized by major family members, such as the nerve growth factors (NGF), brain-derived neurotrophic factors (BDNF) and neurotrophin-3 (NT-3), which have been demonstrated here to lack coding sequence variations and follow the regime of negative selection, highlighting their extremely important conserved role in vertebrate homeostasis. However, in stark contrast, venom NGF secreted as part of the chemical arsenal of the venomous advanced snake family Elapidae (and to a lesser extent Viperidae) have characteristics consistent with the typical accelerated molecular evolution of venom components. This includes a rapid rate of diversification under the significant influence of positive-selection, with the majority of positively-selected sites found in the secreted β-polypeptide chain (74%) and on the molecular surface of the protein (92%), while the core structural and functional residues remain highly constrained. Such focal mutagenesis generates active residues on the toxin molecular surface, which are capable of interacting with novel biological targets in prey to induce a myriad of pharmacological effects. We propose that caenophidian NGFs could participate in prey-envenoming by causing a massive release of chemical mediators from mast cells to mount inflammatory reactions and increase vascular permeability, thereby aiding the spread of other toxins and/or by acting as proapoptotic factors. Despite their presence in reptilian venom having been known for over 60 years, this is the first evidence that venom-secreted NGF follows the molecular evolutionary pattern of other venom components, and thus likely participates in prey-envenomation. [ABSTRACT FROM AUTHOR]

Published

2013