Nicole Lawrence

Mutator Phenotypes Caused by Substitution at a Conserved Motif A Residue in Eukaryotic DNA Polymerase

Eukaryotic DNA polymerase (Pol) δ replicates chromosomal DNA and is also involved in DNA repair and genetic recombination. Motif A in Pol δ, containing the sequence DXXXLYPSI, includes a catalytically essential aspartic acid as well as other conserved residues of unknown function. Here, we used site-directed mutagenesis to create all 19 amino acid substitutions for the conserved Leu612 in Motif A of Saccharomyces cerevisiae Pol δ. We show that substitutions at Leu612 differentially affect viability, sensitivity to genotoxic agents, cell cycle progression, and replication fidelity. The eight viable mutants contained Ile, Val, Thr, Met, Phe, Lys, Asn, or Gly substitutions. Individual substitutions varied greatly in the nature and extent of attendant phenotypic deficiencies, exhibiting mutation rates that ranged from near wild type to a 37-fold increase. The L612M mutant exhibited a 7-fold elevation of mutation rate but essentially no detectable effects on other phenotypes monitored; the L612T mutant showed a nearly wild type mutation rate together with marked hypersensitivity to genotoxic agents; and the L612G and L612N strains exhibited relatively high mutation rates and severe deficits overall. We compare our results with those for homologous substitutions in prokaryotic and eukaryotic DNA polymerases and discuss the implications of our findings for the role of Leu612 in replication fidelity.

Novel alpha D-conopeptides and their precursors identified by cDNA cloning define the D-conotoxin superfamily.

AlphaD-conotoxins are peptide inhibitors of nicotinic acetylcholine receptors (nAChRs) first described from Conus vexillum (alphaD-VxXIIA-C and renamed here to alphaD-VxXXA, alphaD-VxXXB, and alphaD-VxXXC). In this study, we report cDNA sequences encoding D-superfamily conopeptides identified in the Clade XII Conidae Conus vexillum, Conus capitaneus, Conus mustelinus, and Conus miles, together with partial sequences of corresponding peptides from this family. The D-superfamily signal peptide sequences display greater heterogeneity than reported for other conotoxin superfamilies. Phylogenetic analysis of the relationships among alphaD-conotoxin precursors reveals two distinct groups containing either an EMM or AVV signal peptide sequence motif. Homodimer and heterodimer combinations of predicted mature toxin sequences likely account for the partial amino acid sequences and mass values observed for several of the native dimeric peptide components identified in C. capitaneus, C. miles, and C. mustelinus venom. The discovery of the precursors and several novel conotoxins from different species defines this large conotoxin family and expands our understanding of sequence diversification mechanisms in Conus species.

Gene-flow between populations of cotton bollworm Helicoverpa armigera (Lepidoptera: Noctuidae) is highly variable between years.

Both large and small scale migrations of Helicoverpa armigera Hübner in Australia were investigated using AMOVA analysis and genetic assignment tests. Five microsatellite loci were screened across 3142 individuals from 16 localities in eight major cotton and grain growing regions within Australia, over a 38-month period (November 1999 to January 2003). From November 1999 to March 2001 relatively low levels of migration were characterized between growing regions. Substantially higher than average gene-flow rates and limited differentiation between cropping regions characterized the period from April 2001 to March 2002. A reduced migration rate in the year from April 2002 to March 2003 resulted in significant genetic structuring between cropping regions. This differentiation was established within two or three generations. Genetic drift alone is unlikely to drive genetic differentiation over such a small number of generations, unless it is accompanied by extreme bottlenecks and/or selection. Helicoverpa armigera in Australia demonstrated isolation by distance, so immigration into cropping regions is more likely to come from nearby regions than from afar. This effect was most pronounced in years with limited migration. However, there is evidence of long distance dispersal events in periods of high migration (April 2001-March 2002). The implications of highly variable migration patterns for resistance management are considered.

Interaction of Tarantula Venom Peptide ProTx-II with Lipid Membranes is a Prerequisite for its Inhibition of Human Voltage-gated Sodium Channel NaV1.7

ProTx-II is a disulfide-rich peptide toxin from tarantula venom able to inhibit the human voltage-gated sodium channel 1.7 (hNaV1.7), a channel reported to be involved in nociception, and thus it might have potential as a pain therapeutic. ProTx-II acts by binding to the membrane-embedded voltage sensor domain of hNaV1.7, but the precise peptide channel-binding site and the importance of membrane binding on the inhibitory activity of ProTx-II remain unknown. In this study, we examined the structure and membrane-binding properties of ProTx-II and several analogues using NMR spectroscopy, surface plasmon resonance, fluorescence spectroscopy, and molecular dynamics simulations. Our results show a direct correlation between ProTx-II membrane binding affinity and its potency as an hNaV1.7 channel inhibitor. The data support a model whereby a hydrophobic patch on the ProTx-II surface anchors the molecule at the cell surface in a position that optimizes interaction of the peptide with the binding site on the voltage sensor domain. This is the first study to demonstrate that binding of ProTx-II to the lipid membrane is directly linked to its potency as an hNaV1.7 channel inhibitor.

Population dynamics and gene flow of Helicoverpa armigera (Lepidoptera : Noctuidae) on cotton and grain crops in the Murrumbidgee Valley, Australia

Abstract The population dynamics of Helicoverpa armigera (Hübner) (Lepidoptera: Noctuidae) in the Murrumbidgee Valley, Australia, has been characterized using five highly variable microsatellite loci. In the 2001–2002 growing season, there were very high levels of migration into the Murrumbidgee Valley with no detectable genetic structuring, consistent with previous analyses on a national scale. By contrast, there was significant genetic structuring over the 2002–2003 growing season, with three distinct genetic types detected. The first type corresponded to the first two generations and was derived from local individuals emerging from diapause and their progeny. The second genetic type corresponded to generation 3 and resulted from substantial immigration into the region. There was another genetic shift in generation 4, which accounts for the third genetic type of the season. This genetic shift occurred despite low levels of immigration. During the third generation of the 2002–2003 growing season, different population dynamics was characterized for H. armigera on maize, Zea mays L., and cotton Gossipium hirsutum L. Populations on cotton tended to cycle independently with very little immigration from outside the region or from maize within the region. Maize acted as a major sink for immigrants from cotton and from outside the region. If resistance were to develop on cotton under these circumstances, susceptible individuals from maize or from other regions would not dilute this resistance. In addition, resistance is likely to be transferred to maize and be perpetuated until diapause, from where it may reemerge next season. If low levels of immigration were to occur on transgenic cotton, this may undermine the effectiveness of refugia, especially noncotton refugia.

Recombinant chimeric proteins generated from conserved regions of Plasmodium falciparum merozoite surface protein 2 generate antiparasite humoral responses in mice.

The merozoite surface protein 2 of P. falciparum is highly polymorphic in nature, but has regions of almost complete conservation at its N‐ and C‐termini. We produced a chimeric recombinant protein comprising these regions only (hereafter termed NC). Mice immunized with the NC antigen produce antibodies at levels comparable to those immunized with 1624, a full‐length recombinant protein representing MSP2 from P. falciparum. Antisera raised against NC recognized P. falciparum schizonts by IFA and a P. falciparum protein of Mr 45 kDa by Western blot. However, antibody specificities were observed to differ between anti‐NC and anti‐1624 sera, and this resulted in differences in parasite recognition, despite similar levels of antibodies having been produced. The response to the NC antigen was also shown to be restricted in some mice (H2‐d), but this was overcome by including appropriate T‐cell help, which was accomplished by creating recombinant protein chimeras that contained NC and T‐helper epitopes from Tetanus toxoid, or MSP119 from P. berghei.

Spider peptide toxin HwTx-IV engineered to bind to lipid membranes has an increased inhibitory potency at human voltage-gated sodium channel hNaV1.7.

The human voltage-gated sodium channel sub-type 1.7 (hNaV1.7) is emerging as an attractive target for the development of potent and sub-type selective novel analgesics with increased potency and fewer side effects than existing therapeutics. HwTx-IV, a spider derived peptide toxin, inhibits hNaV1.7 with high potency and is therefore of great interest as an analgesic lead. In the current study we examined whether engineering a HwTx-IV analogue with increased ability to bind to lipid membranes would improve its inhibitory potency at hNaV1.7. This hypothesis was explored by comparing HwTx-IV and two analogues [E1PyrE]HwTx-IV (mHwTx-IV) and [E1G,E4G,F6W,Y30W]HwTx-IV (gHwTx-IV) on their membrane-binding affinity and hNaV1.7 inhibitory potency using a range of biophysical techniques including computational analysis, NMR spectroscopy, surface plasmon resonance, and fluorescence spectroscopy. HwTx-IV and mHwTx-IV exhibited weak affinity for lipid membranes, whereas gHwTx-IV showed improved affinity for the model membranes studied. In addition, activity assays using SH-SY5Y neuroblastoma cells expressing hNaV1.7 showed that gHwTx-IV has increased activity at hNaV1.7 compared to HwTx-IV. Based on these results we hypothesize that an increase in the affinity of HwTx-IV for lipid membranes is accompanied by improved inhibitory potency at hNaV1.7 and that increasing the affinity of gating modifier toxins to lipid bilayers is a strategy that may be useful for improving their potency at hNaV1.7.

Biophysical properties of Nav1.8/Nav1.2 chimeras and inhibition by µO‐conotoxin MrVIB

BACKGROUND AND PURPOSE Voltage‐gated sodium channels are expressed primarily in excitable cells and play a pivotal role in the initiation and propagation of action potentials. Nine subtypes of the pore‐forming α‐subunit have been identified, each with a distinct tissue distribution, biophysical properties and sensitivity to tetrodotoxin (TTX). Nav1.8, a TTX‐resistant (TTX‐R) subtype, is selectively expressed in sensory neurons and plays a pathophysiological role in neuropathic pain. In comparison with TTX‐sensitive (TTX‐S) Navα‐subtypes in neurons, Nav1.8 is most strongly inhibited by the µO‐conotoxin MrVIB from Conus marmoreus. To determine which domain confers Nav1.8 α‐subunit its biophysical properties and MrVIB binding, we constructed various chimeric channels incorporating sequence from Nav1.8 and the TTX‐S Nav1.2 using a domain exchange strategy.

Redesigned spider peptide with improved antimicrobial and anticancer properties

Gomesin, a disulfide-rich antimicrobial peptide produced by the Brazilian spider Acanthoscurria gomesiana, has been shown to be potent against Gram-negative bacteria and to possess selective anticancer properties against melanoma cells. In a recent study, a backbone cyclized analogue of gomesin was shown to be as active but more stable than its native form. In the current study, we were interested in improving the antimicrobial properties of the cyclic gomesin, understanding its selectivity toward melanoma cells and elucidating its antimicrobial and anticancer mode of action. Rationally designed analogues of cyclic gomesin were examined for their antimicrobial potency, selectivity toward cancer cells, membrane-binding affinity, and ability to disrupt cell and model membranes. We improved the activity of cyclic gomesin by ∼10-fold against tested Gram-negative and Gram-positive bacteria without increasing toxicity to human red blood cells. In addition, we showed that gomesin and its analogues are more toxic toward melanoma and leukemia cells than toward red blood cells and act by selectively targeting and disrupting cancer cell membranes. Preference toward some cancer types is likely dependent on their different cell membrane properties. Our findings highlight the potential of peptides as antimicrobial and anticancer leads and the importance of selectively targeting cancer cell membranes for drug development.

Development of cell-penetrating peptide-based drug leads to inhibit MDMX:p53 and MDM2:p53 interactions

The transcription factor p53 has a tumor suppressor role in leading damaged cells to apoptosis. Its activity is regulated/inhibited in healthy cells by the proteins MDM2 and MDMX. Overexpression of MDM2 and/or MDMX in cancer cells inactivates p53, facilitating tumor development. A 12‐mer dual inhibitor peptide (pDI) was previously reported to be able to target and inhibit MDMX:p53 and MDM2:p53 interactions with nanomolar potency in vitro. With the aim of improving its cellular inhibitory activity, we produced a series of constrained pDI analogs featuring lactam staples that stabilize the bioactive helical conformation and fused them with a cell‐penetrating peptide to increase cytosol delivery. We compared pDI and its analogs on their inhibitory potency, toxicity, and ability to enter cancer cells. Overall, the results show that these analogs keep their nanomolar affinity for MDM2 and MDMX and are highly active against cancer cells.