Gelsolin-Mediated Actin Filament Severing in Crowded Environments

Heidings, James

01 January 2020

Actin is an essential cytoskeletal protein that plays key roles in several cellular functions such as phagocytosis and cell motility with the help of actin binding proteins (ABPs). Gelsolin is a calcium regulated ABP that severs and caps actin filaments. Gelsolin helps control actin filament assembly dynamics that are required for cell survival. Cleavage products of gelsolin lead to Familial Amyloidosis, Finnish type, and conformational changes to gelsolin are implicated in disease progression. The majority of in vitro studies of gelsolin and actin have been performed in dilute buffer conditions which do not simulate the molecular interactions occurring in the intracellular environment. The intracellular space is packed with many macromolecules such as carbohydrates and other proteins. These macromolecules induce steric hindrance and excluded volume effects and have been shown to alter protein-protein interactions and protein conformations. We hypothesize that gelsolin and actin filaments present in crowded environments will produce greater gelsolin severing activity due to steric hinderance and induced conformational changes. To test this hypothesis, we have visualized actin filament severing by gelsolin in solution with macromolecular crowders utilizing total internal reflection fluorescence (TIRF) microscopy. Steady-state average filament lengths and filament length distributions were analyzed to determine the effect crowding has on gelsolin-mediated filament severing. Real-time filament severing assays visualized by TIRF allowed us to compare gelsolin's severing efficiency in the presence of crowders to those in dilute buffer conditions. Co-sedimentation assays were performed in order to determine the effect of crowding on gelsolin binding to actin filaments. Taken together, this study demonstrates that macromolecular crowding modulates gelsolin-mediated actin filament severing activities, offering insights into the interactions between actin and gelsolin inside the cell. These insights will deepen our understanding of in vivo cytoskeletal regulation which is linked to cell physiology and may aid researchers studying actin-related diseases.

Medical Biotechnology

Single Cell Forensic Genomics - DNA Profiling of Micromanipulated Single Spermatozoa

Hardin, Haley

01 January 2020

Current U.S. National guidelines allow for the collection of sexual assault evidence up to 5 days after the incidence occurs. In these cases, the ability to obtain an autosomal STR (aSTR) profile of the male donor in these cases diminishes as the time interval increases. This inability to recover an aSTR profile from the semen donor is not due to a complete lack of sperm cells, as studies have frequently shown that sperm persists in the vaginal canal or cervix up to 10 days post coitus. Thus, the inability to recover an aSTR profile of the sperm donor is likely due to a low quantity of sperm cells and/or degradation of sperm cells, which pose significant problems to existing DNA extraction and typing methods. A typical DNA workflow for this type of evidence in a forensic casework laboratory includes the use of a differential extraction to separate sperm cells from non-sperm cells. These often harsh extraction methods can cause degraded and fragile sperm cells to be prematurely lysed into the non-sperm cell fraction. The significant amounts of vaginal epithelial cells in the sample can overwhelm the minute number of sperm cells present in this fraction, resulting in a complete masking of the male profile. For most sexual assault samples collected more than 48-72 hours after an incident, Y-STR analysis might be used instead of aSTR analysis, as it allows for an increased time frame of DNA recovery by detecting only the male donor Y-haplotype, circumventing the need for a differential extraction and avoiding potential competition during amplification. However, Y-STR loci are part of the non-recombining region of the Y-chromosome, and thus do not have the same discrimination power of aSTR loci. Therefore, enhanced methods for the recovery of sperm cells that allow researchers to bypass the limitations of a typical DNA workflow and obtain an aSTR profile need to be developed. This study aimed to do so by utilizing enhanced, non-standard methods to collect individual sperm cells via direct physical recovery from semen containing samples. Optimized direct lysis and micro-volume aSTR amplification were also used in order to obtain DNA profiles of the sperm donor. The quality of the obtained DNA profiles was evaluated using metrics such as allele recovery, stutter occurrence and percentage, and drop-in allele levels. Using these developed methods, the ability to analyze single sperm cells was demonstrated and the minimum number of sperm cells required in order to obtain probative and reliable DNA profiles was determined.

Medical Biotechnology

BMP-7 Ameliorates Ponatinib Induced Muscle Cell toxicity: An in vitro and in vivo Study

Srivastava, Ayushi

01 January 2022

Tyrosine Kinase Inhibitors associated muscle complaints like cramps, pain, and weakness are a few of the concerns contributing to declined disease control and quality of life. In this study, we investigated whether Ponatinib, a 3rd generation TKI, induces muscle toxicity in both In Vitro and In Vivo models and expand BMP-7 as a possible treatment option for its attenuation. For the In vitro study, Sol-8, a mouse myogenic cell line was exposed to Ponatinib and BMP-7 for 24hrs each. For the In vivo study, C57BL/6J mice were injected and euthanized after 14 days. The soleus muscle was isolated and used for experimentation. Both the studies were conducted with 3 groups: Control, Ponatinib, and Ponatinib+BMP-7. Ponatinib-induced muscle toxicity via apoptosis was established by TUNEL Assay, pro-apoptotic markers- Caspase 3, BAX, and anti-apoptotic marker Bcl2 via Immunocytochemistry and Immunohistochemistry. For the In vivo study, further confirmations of the above-mentioned apoptotic markers were done by RT-PCR. Ponatinib-induced muscle myopathy and loss in muscle function were also determined along with the effect on apoptotic pathway proteins PTEN and AKT. A significant (p < 0.05) increase in apoptotic positive nuclei as well as positive cells for pro-apoptotic markers was observed in Ponatinib treatment groups both in vitro and in vivo along with loss of muscle function and adverse muscle remodeling. Whereas BMP-7 treatment significantly (p < 0.05) attenuated Ponatinib-induced apoptosis, restored muscle function, and improved muscle remodeling. The result of our study suggests that Ponatinib-induces apoptotic cell death in skeletal cells which was attenuated by BMP-7.

Medical Biotechnology

Downregulation of miR-34a via Calorie Restriction Regulates Lipid Metabolism in the Liver of Long-living Ames Dwarf Mice

Ashiqueali, Sarah

01 January 2021

Ames dwarf mice (df/df) display delayed aging relative to their normal siblings, living approximately 40-60% longer. As such, investigating the mechanisms that enable these organisms to have superior life expectancies may prove useful in developing therapies to slow aging and deter age-related disease. Nonalcoholic fatty liver disease (NAFLD) is a condition that is characterized by the accumulation of excess adipose tissue in the liver. Interestingly, its prevalence tends to increase with age with an incidence rate of greater than 40% in individuals over the age of 60. Previous studies highlight the potential of calorie restriction (CR) in promoting longevity, but little is known about its effects on the biomolecular processes that govern NAFLD. In this study, we explored the livers of Ames dwarf mice following 6 months of continuous calorie-restriction and discovered significant down regulation of candidate miR-34a, an established biomarker for fatty liver. Using qPCR and western blot, we found miR-34a to be correlated with the expression of age-related and lipid trafficking mRNA and protein. Specifically, CR upregulated Sirt1 in the Ames dwarf liver and subsequently induced gluconeogenesis and lipid catabolism. To verify the role of miR-34a in influencing fatty acid metabolism, we transfected the human liver cancer (HepG2) cell line with miR-34a mimic and observed its effect on direct targets SIRT1, AMPKa, and PPARa which are believed to influence downstream lipid transport genes. In all, our findings suggest that CR is a robust driver of the SIRT1 signaling pathway which reverses the pathology associated with age-related diseases by influencing insulin signaling in the Ames dwarf liver thereby improving fatty acid oxidation and cholesterol efflux and maintaining lipid turnover via autophagy.

Medical Biotechnology

Effects of PCSK9i on Doxorubicin Induced Necroptosis

Imaralu, Omonzejie

01 January 2022

Doxorubicin (Dox) is a potent and widely used anthracycline for cancer chemotherapy. However, the prevalence of Dox induced cardiotoxicity (DIC) in children and adolescents receiving Dox treatment is a major concern. While the exact molecular mechanisms of DIC remains to be fully elucidated, studies have reported cell death (apoptosis) as a major molecular mechanism in the occurrence of DIC. However, the presence of necroptosis in young DIC remains unknown. Therefore, in this study, we investigated the possible occurrence of necroptotic cell death in DIC in young mice in-vivo to delineate underlying pathological mechanism and the therapeutic ability of proprotein convertase substilisin/Kexin 9 inhibitors (PCSK9i) to attenuate doxorubicin induced necroptotic cell death and adverse cardiac remodeling. C57BL6 mice (6 + 2 weeks of age) were divided into three groups and administered the following treatments: Control (saline), Dox and Dox+PCSK9i. At D14 echocardiography was performed to examine heart function. Heart tissues were collected and analyzed for protein expression using immunohistochemistry and western blot to determine necroptosis and necroinflammation. Adverse cardiac remodeling was determined with histology stains for fibrosis and cardiac hypertrophy. Dox treatment significantly (p < 0.05) increased the expression of necroptotic markers [Receptor interacting Serine/Threonine kinase 1 and 3 (RIPK1, RIPK3) and Mixed Lineage kinase domain-Like (MLKL)], Necroinflammation markers [interleukin-33 (IL33) and interleukin-1α (IL-1α)], pro-inflammatory cytokines [interleukin- 6 (IL-6) and tumor necrosis factor alpha (TNF-α)], and induced adverse cardiac remodeling with significant increase (p < 0.05) in cardiac hypertrophy and fibrosis and significantly (p < 0.05) reduced cardiac function when compared to control. However, PCSK9i treatment showed a reduction in expression of necroptotic markers, necroinflammation markers and pro-inflammatory cytokines IL-6 and TNF-α, significant (p < 0.05) reductions in cardiac hypertrophy and fibrosis with improved heart function. Lastly, the result of our study shows that PCSK9i attenuates doxorubicin induced necroptosis and cardiac remodeling

Medical Biotechnology

Development of Curcumin-loaded Nanoparticles for Drug Delivery Optimization in the Treatment of Peripheral Nerve Injury

Giannelli, Giuliana

01 January 2022

Peripheral nerve injuries (PNI) affect 20 million people, with over 200,00 nerve repairs performed annually in the United States alone. Nerve conduits (NCs) are a commonly employed treatment for injured nerve segments under 3 cm, but unsatisfactory outcomes have been reported for larger gaps. This is in part due to the lack of bioactive agents such as stem cells or growth factors incorporated into FDA-approved NCs. While they have been experimentally shown to promote peripheral nerve regeneration (PNR), their inherent variability, harvesting complexity, and sometimes inadvertently high biological activity pose great regulatory hurdles. Therefore, plant extracts have become an attractive alternative area of bioactive agents proven to improve PNR while overcoming these issues, one of which is curcumin. However, studies largely use unoptimized curcumin which presents an issue as it is hydrophobic and degrades quickly in aqueous solutions. In this study, a nano-formulation comprised of tannic acid and polyvinylpyrrolidone (TA-PVP) was developed to encapsulate curcumin and optimize its delivery to cells. Results show that the developed Cur-TA-PVP nanoparticles (NPs) had an average size of 220 nm, a surface charge of -35mV, and a polydispersity index of 0.3. Further, curcumin was shown to be localized within the core of the NP. This significantly increased the colloidal stability, decreased the degradation rate, and promoted the slow release of curcumin in aqueous solutions. The 2,2-diphenyl-1-picrylhydrazyl (DPPH) radical scavenging activity of the Cur-TA-PVP NPs was also shown to be superior as compared to free curcumin. Finally, fluorescence microscopy revealed a significantly higher concentration of curcumin in SH-SY5Y, S16 rat Schwann cells, and J774 murine macrophages when delivered via NPs. These results collectively provide evidence for the improved physicochemical properties of the nano-curcumin, which led to improved delivery to cells. Therefore, this formulation has the necessary attributes for incorporation into NCs to promote functional recovery following PNI.

Medical Biotechnology

Development of a Non-Human Primate Model for Staphylococcus aureus Nasal Carriage

Lasseter, Amanda

01 January 2018

Staphylococcus aureus nasal carriage (SANC) is largely asymptomatic, but presents a risk of autoinfection and dissemination to new immunocompromised hosts. SA disease states range from mild cutaneous infections to life-threatening bacteremia. Historically utilized rodent models do not naturally carry SA in the nose, are insufficient in longitudinal SANC experimentation, and lack immune factors that are vital in human clearance of SA. The nasal passages of non-human primates are similar anatomically and histologically, and reproductive mucosal studies have shown similar immune responses to pathogens and human-relevant microbial profiles. Seventeen captive pigtailed macaques (Macaca nemestrina) were found to naturally carry SA in the nose and pharynx, while topical mupirocin ointment effectively decolonized SA, similar to humans. Colonization was established with a human-relevant inoculum of 104 SA CFUs per nostril in four independent experiments, including with a human isolate (ST398). Autologous and non-autologous macaque strains were carried similarly in load and duration, each surviving over 40 days. Animals that cleared SA showed a rapid neutrophilic innate response, with up-regulation of IL-8, MCP-1, and IL-1β following inoculation, as observed in human hosts. Assessment of the nasal microbiome of pigtailed macaques and humans demonstrated similar relative abundance of the most prevalent genera: Staphylococcus, Corynebacterium, and Acinetobacter. Collectively, these multidimensional analyses provide evidence that the pigtailed macaque is a novel physiological model of human SANC that may be useful for testing novel SA decolonization strategies.

Medical Biotechnology

The Microbial Ecosystem of Beer Spoilage and Souring: Competition and Cooperation in the Age of Bioinformatics

Kettring, Andrew

01 January 2017

The brewing industry generates $350 billion in revenue in the US annually, representing 1.9% of the gross domestic product. Spoilage is a persistent problem throughout production and distribution that causes economic loss, and is therefore meticulously avoided. Contrarily, artisanal sour beers are necessarily produced by a diverse variety of these spoilage organisms metabolically interacting in symbiosis as a microbial ecosystem. We sought to gain insight into factors driving assembly of microbial communities by testing a long-debated Darwinian hypothesis. A collection of community members were screened in co-culture and novel bioinformatics tools were developed to predict observed interactions. A fundamental understanding of these relationships is paramount to beer production and sets a precedent for the study of similar microbial communities that impact human health.

Medical Biotechnology

Exacerbation of ΔEFP Sickness in Escherichia coli By an Uncharacterized RNA Helicase

Wingo, Robert

01 January 2018

In Escherichia coli, growth is rate-limited by translation capacity [1]. Stalled ribosomes have profound effects on a cell such as altered mRNA abundance, decreased ribosome availability, and an imbalanced proteome. The absence of elongation factor P (EF-P), a universally conserved transpeptidation enhancer, presents an extreme example of this scenario, wherein ribosomes accumulate disproportionately onto messages that are more slowly translated and cell growth becomes notably impaired. We discovered that faster-growing cells arise spontaneously in Δefp cultures, suggesting that translation defects could be circumvented by mutating other genes. This thesis presents a genetic and biochemical analysis of a mechanism Δefp cells employ to overcome translation stress. Using a dual luciferase reporter system, we found that transpeptidation remained hindered in the faster growing Δefp cells. Whole genome sequencing of several fast-growing strains revealed mutations in a poorly characterized RNA helicase called HrpA. We determined that deletion of hrpA, or mutations at several conserved residues critical for HrpA's function, was sufficient to improve the fitness of Δefp cells. HrpA is a DEAH-box RNA helicase and represents a large class of enigmatic proteins that use ATP to restructure cellular RNAs; however, it's direct function in cellular physiology has yet to be clearly demonstrated [2, 3]. Several HrpA mutants were engineered to interrogate the molecular mechanism of HrpA and how its function impairs Δefp cells. Complementation in Δefp ΔhrpA cells showed that a number of these mutants were unable to restore sickness, suggesting they were defective in key aspects of RNA processing. It was discovered that wild-type HrpA is associated with actively translating ribosomes and several of the inactive HrpA mutants impose substantial deleterious effects on translation and ribosome production. In sum, the work presented here describes a mechanism by which cells overcome translation stress involving a novel genetic and biochemical relationship between EF-P and HrpA.

Medical Biotechnology

The Institutional basis of national advantage in biotechnology

Bartholomew, Susan

January 1996

No description available.

Biotechnology -- Research.