Carl S. Lieb

Mojave rattlesnakes (Crotalus scutulatus scutulatus) lacking the acidic subunit DNA sequence lack Mojave toxin in their venom

The venom composition of Mojave rattlesnakes (Crotalus scutulatus scutulatus) differs in that some individuals have Mojave toxin and others do not. In order to understand the genetic basis for this difference, genomic DNA samples from Mojave rattlesnakes collected in Arizona, New Mexico, and Texas were analyzed for the presence of DNA sequences that relate to the acidic (Mta) and basic (Mtb) subunits of this toxin. DNA samples were subjected to PCR to amplify nucleotide sequences from second to fourth exons of the acidic and basic subunits. These nucleotide sequences were cloned and sequenced. The nucleotide sequences generated aligned exactly to previously published nucleotide sequences of Mojave toxin. All DNA samples analyzed generated product using the basic subunit primers, and aligned identically to the Mtb nucleotide sequence. However, only 11 out of the 14 samples generated a product with the acidic subunit primers. These 11 sequences aligned identically to the Mta nucleotide sequence. The venom from the three snakes whose DNA did not amplify with the acidic subunit primers were not recognized by antibodies to Mojave toxin. This suggests that snakes with venom lacking Mojave toxin also lack the productive nucleotide sequence for the acidic subunit in their DNA.

Creatine Kinases of Amphibians and Reptiles: Evolutionary and Systematic Aspects of Gene Expression

The creatine kinases of amphibians and reptiles are evaluated in terms of their genetic variability beyond that of allelic differentiation. One character, the number of loci controlling creatine kinase, is invariant; all investigated species express two loci (Ck-A and Ck-C). Amphibians and reptiles vary in their tissue specificity of creatine kinase expression and in the ability to form interlocus and intralocus heterodimers. The restriction of expression to fewer tissues and the loss of the ability to form heterodimers are interpreted to be derived states. The inferred evolutionary polarity in these variable characters allows their application in phyletic studies of amphibians and reptiles.

History of Science--With Labs.

We describe here an interdisciplinary lab science course for non-majors using the history of science as a curricular guide. Our experience with diverse instructors underscores the importance of the teachers and classroom dynamics, beyond the curriculum. Moreover, the institutional political context is central: are courses for non-majors valued and is support given to instructors to innovate? Two sample projects are profiled.

Differences in fibrinolysis and complement inactivation by venom from different northern blacktailed rattlesnakes (Crotalus molossus molossus)

Venom from 72 different Crotalus molossus molossus rattlesnakes was examined for fibrinolysis and for their ability to inactivate human complement. The fibrinolytic activity of the venoms was variable, but smaller (younger) snakes had less fibrinolytic activity than larger (older) snakes. Major differences between the venoms was detected by isoelectric focusing, and reflected in the number and pI of the proteins with fibrinolytic activity. Of the 72 venoms tested, ten had no effect and three had low activity on complement. The rest of the venoms strongly inactivated complement. The snakes with no activity on complement measured 55 cm or less in length, except for one snake which measured 53 cm and completely inactivated complement. Two larger snakes (76 and 84 cm) had a reduced complement-inactivating activity. Some venoms strongly hydrolyzed C2, whereas others had mild or no effect on this complement component. The attack on C3 was variable: some had no effect on C3, while other venoms produced a 125,000 mol. wt protein, which was recognized by antibodies to C3. Only mild hydrolysis of C4 was evident in serum treated with some venoms. No relationship was evident between the venom properties of this species and geographical distribution. Venom variability is an important clinical reality, and is an important consideration when attempting to isolate proteases from this snake species for further study.

Hemorrhagic and mojave toxins in the venoms of the offspring of two mojave rattlesnakes (Crotalus scutulatus scutulatus)

1. The venoms of two Mojave rattlesnakes and those of their offsprings were analyzed for Mojave toxin and hemorrhagic toxin. 2. The venom of one female, collected in Pima County, Arizona, and the venoms of her six offspring contained hemorrhagic toxin but not Mojave toxin (venom B). 3. The venom of the second female, captured in El Paso County, Texas, contained both toxins (A+B venom). Of her 10 offspring, five contained venom with both toxins, two had hemorrhagic toxin only, and three contained neither toxin. 4. Venoms that caused hemorrhage also inactivated complement. A pool of the venoms of the venom B offspring was less toxic than adult pooled venom A.

Antibody detection of venom protein variation within a population of the rattlesnake Crotalus v. viridis

As a preliminary investigation into intra-population variation in venom proteins in the prairie rattlesnake, Crotalus v. viridis, we analyzed a small number (11) of venom samples from extreme western Texas and adjoining New Mexico by electrophoresis and Western blotting methods. A monoclonal antibody raised against hemorrhagic toxin in C. atrox venom (CA-P-8) recognized all the venoms, but none was recognized by a monoclonal antibody raised against a hemorrhagic toxin in C. m. molossus venom (CMM-1). All the venoms were recognized by an anti-L-amino acid oxidase (CSS20) monoclonal antibody, but none was recognized by an anti-Mojave toxin antibody (CSS12). An antibody (AF5) against a protease in C. s. scutulatus venom that inactivates complement recognized all the venoms except the venom from one young snake. The principal individual venom differences were in the amounts of various venom components, although qualitative differences were noted. The principal similarities lie in the molecular weights of most of the venom proteins. Intrapopulational mobility differences were more pronounced in venom proteins separated by isoelectric focusing and PAGE without SDS and 2-mercaptoethanol.

Genetic Basis for Variation of Metalloproteinase-Associated Biochemical Activity in Venom of the Mojave Rattlesnake (Crotalus scutulatus scutulatus)

The metalloproteinase composition and biochemical profiles of rattlesnake venom can be highly variable among rattlesnakes of the same species. We have previously shown that the neurotoxic properties of the Mojave rattlesnake (Crotalus scutulatus scutulatus) are associated with the presence of the Mojave toxin A subunit suggesting the existence of a genetic basis for rattlesnake venom composition. In this report, we hypothesized the existence of a genetic basis for intraspecies variation in metalloproteinase-associated biochemical properties of rattlesnake venom of the Mojave rattlesnake. To address this question, we PCR-amplified and compared the genomic DNA nucleotide sequences that code for the mature metalloproteinase domain of fourteen Mojave rattlesnakes captured from different geographical locations across the southwest region of the United States. In addition, the venoms from the same rattlesnakes were tested for their ability to hydrolyze fibrinogen, fibrin, casein, and hide powder azure and for induction of hemorrhage in mice. Overall, based on genomic sequencing and biochemical data, we classified Mojave rattlesnake venom into four distinct groups of metalloproteinases. These findings indicate that differences in nucleotide sequences encoding the mature proteinase domain and noncoding regions contribute to differences in venom metalloproteinase activities among rattlesnakes of the same species.

Variation in the antigenic characteristics of venom from the mojave rattlesnake (crotalus scutulatus scutulatus)

Venoms from 31 specimens of the Mojave rattlesnake (Crotalus scutulatus scutulatus) were examined to further characterize reported differences among venoms of this species. Twenty-two venoms were recognized by a monoclonal antibody to Mojave toxin, CSS12. Nine venoms were recognized by CA-P-8, a monoclonal antibody produced against the hemorrhagic venom of C. atrox. Seven of these produced strong hemorrhage in mice and were also recognized by polyclonal antibodies (anti-F5) produced against a fraction of Mojave rattlesnake venom that inactivates serum complement. Fractionated venom revealed that CA-P-8 and anti-F5 recognized different proteins. Two of the venoms recognized by CA-P-8 were not recognized by anti-F5 and produced minimal hemorrhage in mice. This suggests that more than one factor may be necessary to induce strong hemorrhage.

Rescuing Perishable Neuroanatomical Information from a Threatened Biodiversity Hotspot: Remote Field Methods for Brain Tissue Preservation Validated by Cytoarchitectonic Analysis, Immunohistochemistry, and X-Ray Microcomputed Tomography

Biodiversity hotspots, which harbor more endemic species than elsewhere on Earth, are increasingly threatened. There is a need to accelerate collection efforts in these regions before threatened or endangered species become extinct. The diverse geographical, ecological, genetic, morphological, and behavioral data generated from the on-site collection of an individual specimen are useful for many scientific purposes. However, traditional methods for specimen preparation in the field do not permit researchers to retrieve neuroanatomical data, disregarding potentially useful data for increasing our understanding of brain diversity. These data have helped clarify brain evolution, deciphered relationships between structure and function, and revealed constraints and selective pressures that provide context about the evolution of complex behavior. Here, we report our field-testing of two commonly used laboratory-based techniques for brain preservation while on a collecting expedition in the Congo Basin and Albertine Rift, two poorly known regions associated with the Eastern Afromontane biodiversity hotspot. First, we found that transcardial perfusion fixation and long-term brain storage, conducted in remote field conditions with no access to cold storage laboratory equipment, had no observable impact on cytoarchitectural features of lizard brain tissue when compared to lizard brain tissue processed under laboratory conditions. Second, field-perfused brain tissue subjected to prolonged post-fixation remained readily compatible with subsequent immunohistochemical detection of neural antigens, with immunostaining that was comparable to that of laboratory-perfused brain tissue. Third, immersion-fixation of lizard brains, prepared under identical environmental conditions, was readily compatible with subsequent iodine-enhanced X-ray microcomputed tomography, which facilitated the non-destructive imaging of the intact brain within its skull. In summary, we have validated multiple approaches to preserving intact lizard brains in remote field conditions with limited access to supplies and a high degree of environmental exposure. This protocol should serve as a malleable framework for researchers attempting to rescue perishable and irreplaceable morphological and molecular data from regions of disappearing biodiversity. Our approach can be harnessed to extend the numbers of species being actively studied by the neuroscience community, by reducing some of the difficulty associated with acquiring brains of animal species that are not readily available in captivity.

Detection of alkaline phosphatase in venom by blotting methods.

Venom alkaline phosphatase was detected using a blotting method following electrophoresis. The enzyme gave strong reactions in some venoms, but was absent in other venoms, some within the same species. The mol. wt of the enzyme is close to 100,000 and its pI is between 3.6 and 4.8. The enzyme was inactivated by EDTA and 2-mercaptoethanol, and lost activity by freezing and thawing. Endogenous venom alkaline phosphatase can interfere with alkaline phosphatase-based detection methods. Pre-screening for endogenous venom alkaline phosphatase is recommended prior to using alkaline phosphatase-based detection methods when studying snake venom.