More Like this

1. Investigating the Role of DNA Interval v377 in Spore Killing by Neurospora crassa Sk-3

   https://doi.org/10.30707/1734473236.364631  

   Okleiteris, Carolina (January 2024, ISU ReD: Research and eData)

   Neurospora crassa is a fungus that serves as a model organism for genetic research. N. crassa Spore killer-3 (Sk-3) is a genetic element transmitted to offspring through spore killing. Sk-3 is located on Chromosome III and it is thought to require two genes for spore killing. These two genes are the poison gene, for killing, and the antidote gene, for resistance to killing. While the Sk-3 resistance gene has been identified (rsk), the Sk-3 killer gene has not. The primary goal of this study is to help identify the killer gene by investigating the role of a DNA interval called v377 in spore killing. To determine if this interval is required for spore killing, a DNA deletion vector (Vector v377) was constructed and used to replace the v377 interval with a hygromycin resistance gene in strain RDGR170.3. My results demonstrate that v377 is required for spore killing. The possibility that v377 is within a gene required for spore killing, or a regulatory element that controls spore killing, is discussed. 

   more » « less
2. Investigating the Role of DNA Interval v375 In Spore Killing by Neurospora crassa Sk-3

   https://doi.org/10.30707/1734473246.481567  

   Marcheschi, Michael (January 2024, ISU ReD: Research and eData)

   Meiotic drive elements, sometimes called selfish genes, are genetic elements that are passed on to their offspring more favorably than other genes. Meiotic drive elements have been observed in many organisms, including fungi of the Neurospora genus. Three different meiotic drive elements, called Spore killers, have been identified in Neurospora fungi. One of these Spore killers is called Spore killer 3 (Sk-3), and the molecular mechanism by which Sk-3 acts as a meiotic drive element is poorly understood. Previous work has identified a genetic locus within Sk-3 that may control spore killing. In this thesis, I investigate an interval of DNA within this locus called v375. Through gene deletion and spore killing assays, I show that deletion of v375 disrupts Sk-3-based spore killing in N. crassa. Possible explanations for why interval v375 is required for spore killing by Sk-3 are discussed. 

   more » « less
3. Investigating Sk-3 Based Spore Killing in Neurospora crassa Through Deletion Analysis of DNA Intervals i383 And i394

   Paulikas, Paulina (January 2025, ISU ReD)

   Neurospora fungi are found around the world. The species N. crassa is a popular model for use in genetics research. N. crassa produces sexual spores, called ascospores, during mating between strains of opposite mating types. N. crassa also produces spore sacs called asci, and each ascus typically contains eight viable ascospores. However, some Neurospora fungi carry selfish genetic elements called Spore killers, and when a strain carrying a Spore killer mates with a spore killing-susceptible strain, asci contain four black viable ascospores and four white inviable ascospores. In this project, I investigated a Spore killer called Sk-3. To act as a selfish genetic element, Sk-3 is thought to require at least two genes, a poison gene and an antidote gene. The Sk-3 antidote gene (rsk) has been identified, but the poison gene has not. The purpose of this study is to help identify the location of the poison gene. To do this, I deleted two DNA intervals (i383 and i394) from a location of the Neurospora genome that may harbor the poison gene. My results indicate that deletion of i383 eliminates spore killing while deletion of i394 has no effect on spore killing. The possibility that i394 overlaps with the poison gene is discussed. 

   more » « less
4. Examining the Mechanism of Spore Sacs Undergoing Sk-3-Based Spore Killing After Deletion Of Neurospora crassa DNA Intervals i382 and i400

   Klann, Makenna (January 2025, ISU ReD: Research and eData)

   Neurospora crassa is a well-known model organism for studying eukaryotic genetics, particularly non-Mendelian inheritance mechanisms such as meiotic drive. In N. crassa, meiotic drive can be observed in fungal spore killing, where Spore killer-3 (Sk-3) is a selfish genetic element transmitted to offspring through spore killing. Sk-3 is thought to contain two principal components: a killer (poison) gene and a resistance (antidote) gene. While the resistance gene (rsk) has been identified, the killer gene remains unknown. Building on previous research that identified a 1.3 kb DNA interval (i350) essential for Sk-3-based spore killing, I analyzed two subintervals, i382 and i400, to narrow down the functional components of the Sk-3 locus. Deletion of i382 does not disrupt spore killing and deletion of interval i400 partially disrupts spore killing but does not eliminate it. Future work should retest the i400 strains in spore killing assays, to determine if the partial spore killing phenotype can be detected in all crosses when larger numbers of rosettes are examined. The findings presented here help narrow down the search for the unknown poison gene involved in spore killing, which is a critical step towards understanding processes that allow for the evolution of Sk-3-type selfish genetic elements. 

   more » « less
5. Identifying the location of the rfk-2 spore killer gene on Chromosome III of Neurospora crassa

   https://doi.org/10.30707/1734473226.462803  

   Patel, Princy (January 2024, ISU ReD: Research and eData)

   Meiotic drivers are selfish genetic elements that skew transmission in their favor. In the filamentous fungus N. crassa, one such meiotic driver is Spore killer-3 (Sk-3). In a cross between Sk-3 and a spore killer-sensitive mating partner (Sk-S), only half of the ascospores (sexual spores) survive. Nearly all of the survivors inherit the genes for spore killing. Previous studies have established that a gene called rfk-2 (required for spore killing) is essential for the spore killing activity of Sk-3. The rfk-2 gene has been mapped to Chromosome III, but its exact location is unknown. The goal of this study is to help identify the exact location of rfk-2. Towards this goal, I investigated a DNA interval called v378. Preliminary findings suggested that this interval may be important for spore killing. To determine if v378 is required for spore killing, I constructed and used a transformation vector to replace v378 with a hygromycin resistance gene (hph+) in an N. crassa Sk-3 strain. Strains deleted of v378 were then crossed with two spore killing-sensitive tester strains. The spore sacs containing ascospores from these crosses were imaged to analyze the effects of replacement of v378 on Sk-3-based spore killing. My findings demonstrate that v378 is required for spore killing. The potential implications of my findings with respect to our understanding of meiotic drive elements, and their potential applications, is discussed. 

   more » « less