The phenomenon of helicopter parenting, or a parent’s overinvolvement in their children’s lives, has been previously studied in populations of college students. Helicopter parenting is associated with negative effects on child well-being and parental closeness in this population. Current research is sparse, however, with very little research examining helicopter parenting in non-college student populations. The current study aims to (1) replicate previous findings on the effects of helicopter parenting in a non-student population; (2) explore the relationship between helicopter parenting and wellbeing substance use, and justice involvement; and (3) examine associations between demographic variables and helicopter parenting. This poster focuses on the methodology being implemented in the current study, as well as an examination of current literature surrounding helicopter parenting.

Terror management theory suggests that the potential for anxiety from the awareness of death can be buffered by a cultural worldview. Mind-body dualism, the belief that the mind and the body are separate, might affect people’s mortality concerns. Given that the body is threatening given its vulnerability to death, individuals who perceive the mind and body as being connected (vs. separate) should experience higher mortality-related thoughts and defense of their cultural beliefs. Past research found that mind-body dualism was related to afterlife belief, which was able to buffer existential concerns (Heflick et al., 2015). Based on these findings, the current research investigated how mind-body dualism moderated the effect of the creaturely body on death-related concerns. The result showed that people who perceived the mind-body relationship as more separate showed significantly fewer death concerns after reading an essay emphasizing the creatureliness of the body, whereas people who held beliefs in a more interrelated mind-body relationship showed heightened death concerns after the creaturely body prime.

Reintroductions have become increasingly common to help restore populations of Texas horned lizards (Phrynosoma cornutum). Reintroduction success of any species can be shaped by many factors including genetics, selection of suitable reintroduction sites, etc. Our primary goal has been to determine whether release techniques- specifically site selection and release method- contribute to the reintroduction success of captive-bred hatchling Texas horned lizards. In 2020 and 2021, we reintroduced over 500 captive-bred hatchling Texas horned lizards from the Ft. Worth, Dallas, and Caldwell Zoos to Mason Mountain WMA (Mason County, TX). Lizards were randomly assigned to one of two release sites and were placed either in clumps of 20+ lizards (Site 2 2020 & Site 1 2021) or were dispersed 5 m from one another (Site 1 2020 & Site 2 2021) at release. We used harmonic radar to track lizards and monitor survivorship outcomes and growth rates from release (September or October) until most lizards began brumating in early December. We found that survival outcomes were associated with both release site (χ22, 509 = 34.5, p<0.0001) and release method (χ22, 509 =15.09, p=0.005). We achieved the highest survivorship (26.4%) when lizards were dispersed at Site 1. Preliminary dietary and prey availability assessments suggest that survivorship differences between locations may be related to differences in food availability. Our findings suggest that future reintroduction attempts may have higher success rates if 1) sites are selected that meet the specific resource requirements of hatchlings, and 2) lizards are dispersed from one another at release.

Anthrax is an infectious disease caused by Bacillus anthracis, which is a spore forming bacterium. Even though the anthrax toxins and capsule, encoded on 2 plasmids pXO1 and pXO2, play crucial role in the pathogenesis of anthrax infection, evidence suggests that chromosomal genes also play a role. The ClpX ATPase was discovered to be crucial for B. anthracis virulence via protection against host antimicrobial peptides. In this study, we want to investigate the role of clpX in regulation of other stressors including acidic stress, temperature stress, salt stress, and non-cell envelope active antibiotics. We found that clpX is necessary for survival in an acidic environment and growth under heat stress. We demonstrate that acidic stress resistance is mediated by the formation of the ClpXP protease using a ClpX complementation plasmid that is incapable of interacting with ClpP. There is no association between clpX with other stressors. We conclude that the ClpX is required for B. anthracis pathogenicity via defenses against host antimicrobial peptides and for survival in an acidic environment. Understanding the role ClpX in the regulation of stress responses will ultimately infer us with new target for either directly combating infection or improving the efficacy of already available medicines.

Impacts of Pollen-Donor Distance and Nutrient Availability on
Reproductive Success in a Carnivorous Plant

Halia Eastburn and John Horner

The maintenance of genetic diversity has important consequences for the survival of plant populations. Because plants are sessile, the distance between plants is often inversely correlated with relatedness. Therefore, the distance between pollen-donor and recipient can determine the level of inbreeding or outbreeding. Both pollen-donor distance and nutrient availability can affect reproductive success in populations of flowering plants. Populations of the carnivorous plant Sarracenia alata have dwindled and become extremely fragmented due to human development and agriculture. The purpose of this study was to examine the effects of pollen-donor distance and prey capture on reproductive success in S. alata. We hand-pollinated flowers with pollen from varying distances [0 m (self-pollinated) and 35, 60, 90, 125, and 190 m], and we prevented prey capture in half of our study plants. We measured seed production and germination to estimate reproductive success. Pollen-donors from greater distances sired a greater number of seeds but pollen-donor distance did not affect germinability. There was no effect of prey capture alone nor an interaction of pollen-donor and prey capture on seed production or germination. More research is needed to understand nutrient allocation for reproduction over multiple years and natural variance in prey capture which might affect reproductive output in subsequent seasons.

Due to habitat loss the Texas horned lizard (THL) (Phrynosoma cornutum) population has declined across its historic range. To date, reintroduction attempts for the species have been unsuccessful, calling into question the suitability of the habitat. Texas horned lizards require suitable thermal habitat to meet their thermoregulatory needs, because of this, understanding the thermal habitat requirements of THLs is important. While the critical temperature limits and preferred body temperatures of THLs are established from laboratory studies, thermal habitat preferences for THLs in the wild are poorly understood. The objective of this study was to determine thermal habitat preferences and home range sizes of reintroduced THLs at Mason Mountain WMA compared to a nearby natural population of THLs on the White Ranch. We also compare the thermal conditions of different microhabitats between the two sites. To compare thermal conditions between the two sites, we used thermal dataloggers to record the temperatures in different microhabitats throughout the day at each study site, then compared how much of the time these data loggers were within the lizard’s optimal temperature range between the two study sites. Home ranges were calculated for lizards from the two study sites and average home range sizes between the two study sites were compared for significant differences. The ground temperature selected by the lizards versus random points were compared between the two study sites. These findings will improve our understanding of THL thermal ecology and reintroduction requirements.

Metal Halide Perovskites (MHPs) are an emerging type of semiconductor for use in electronic devices that produce or utilize light. MHPs have shown advantages over traditional semiconductors such as silicon due to ease of solution processing, high defect tolerance (defects are strained chemical bonds and/or missing atoms in the crystal lattice) and tunable emission of light color. MHPs have the chemical structure ABX3 where A is a monovalent cation (+1) such as cesium, methylammonium or formamidinium; B is a divalent cation (+2) such as lead or tin, and X is a halide such as chloride, bromide, or iodide. Their favorable properties have resulted in solar cells capable of 32.5% power conversion efficiency in a tandem perovskite/silicon solar cell. However, MHPs suffer from issues with long term stability brought about by exposure to air and moisture, as well as ion migration under illumination.
Crystal engineering and chemical passivation using small molecules have been implemented to improve the long-term stability and reduce ion migration. Incorporation of small molecules with charged groups onto a MHP helps to mitigate surface defects by occupying surface sites of missing atoms or strained bonds. Recent work has shown incorporation of these small molecules during MHP synthesis results in the formation of two dimensional layers on top of the three-dimensional perovskite crystal resulting in increased long-term stability, resistance to heat and moisture, and reduction in ion migration at grain boundaries. Current work in our lab involves synthesizing thin films of methylammonium lead tribromide by spin coating and incorporating a macrocycle based on triazine molecules for this purpose. This presentation focuses on the effects of triazine treatment on the above perovskite, as evaluated by photoluminescence microscopy, powder x-ray diffraction, and scanning electron microscopy.

Salt-induced diffusiophoresis is the migration of a colloidal particle in water caused by a salt concentration gradient. Recent studies have shown that diffusiophoresis can be used for controlling particle motion, with potential applications in separation science, microfluidics, and enhanced oil recovery. These applications are especially appealing for nanoparticles with host-guest properties such as micelles. In this work, Rayleigh interferometry was used to experimentally characterize diffusiophoresis of tyloxapol micelles in the presence of the strong salting-out agent, sodium sulfate, in water at 25oC. Our results show that micelle diffusiophoresis occurs from high to low salt concentration. A model based on micelle preferential hydration was used to quantitatively explain our findings. At relatively high salt concentrations, liquid-liquid phase separation (LLPS) was observed. Near this phase transition, micelle Brownian mobility was found to dramatically decrease, making micelle diffusiophoresis the dominant transport mechanism. Our work suggests that salting-out agents and proximity to LLPS can be used to control the motion of micelles and hydrophilic nanoparticles in general.

Catalases are a class of metalloenzymes responsible for the protection of cells from damage caused by hydrogen peroxide by converting it into water and oxygen. Manganese-based catalase (MnCAT) has been identified in different organisms as an antioxidant, raising the interest in developing small molecules as biomimetic models. A Mn(III) complex of pyclen, a 12-membered ring pyrinophane macrocycle, has previously shown to be a functional mimic of MnCAT in our laboratory. In the present study, modifications of the pyridinophane macrocycle were used to evaluate their impact on the catalytic disproportionation of hydrogen peroxide. Two series of ligands were studied: (1) varying the number of pyridine moieties within the macrocycle, and (2) substitutions in the 4-position of the pyridine ring. pH-potentiometric titrations were used to determine the formation constants (log ß) of each manganese complex, which allowed us to derive speciation curves in solution. The initial rates method was used to calculate the kinetic-relevant parameters for the disproportionation reaction. The results emphasize the effect of structural differences of the ligand on modulating the reactivity of manganese, which are the basis of a mechanistic study of the reaction that is currently underway.

N-alkylation of amino acid-containing pharmaceuticals has been shown to increase their respective oral availability and membrane diffusion. Macrocycles, too, have been an interest in modern drug design due to their ability to have a dynamic conformation and adopt a chameleon-like property to enhance the ability for the drug to be properly delivered in a multitude of environments, and similarly macrocycle's ability to fully envelope an active site to block enzymatic activity. In this project, four novel N-alkylated amino acid-linked triazine macrocycles were synthesized from cyanuric chloride using BOC-hydrazine, an N-alkylated amino acid, and dimethylamine. Coupling of the amino acids with EDC to form the acetal product and further acidification and removal of protecting groups with trifluoroacetic acid yielded macrocycles in good yield. Characterization via 1D and 2D NMR reveals the emergence of different conformations in varying proportions. These conformations result from by the restricted rotation around the Ar-N bonds of both the hydrazine and amino acid of the macrocycles. A previous, non N-alkylated, glycine macrocycle was used as a reference compound, and the emergence of the different conformations was not observed for this molecule. Furthermore, the N-methylated glycine macrocycle displayed an asymmetric configuration, whereas the proline macrocycle was too rigid around the Ar-N of the amino acid to form the different rotamers. The successful synthesis of these N-alkylated amino acid macrocycles shows that further customization of these triazine macrocycles is possible.