Causes and Consequences of Mitochondrial Variation in Caenorhabditid Nematodes

Hicks, Kiley Ann

01 January 2012

Mitochondria are dynamic organelles that harbor their own stream-lined genome and generate much of the ATP necessary to sustain eukaryotic life via an electron transport chain (ETC). Because of the central role for mitochondria in organismal physiology, mitochondrial genetic and phenotypic variation can alter organismal fitness and affect population genetic and evolutionary outcomes. Despite the far-reaching relevance of mitochondria to evolutionary processes and human health, we lack a basic understanding of the causes and consequences of mitochondrial genetic and phenotypic variation. In this thesis, I quantified mitochondrial reactive oxygen species (ROS), membrane potential (δΨM), and mitochondrial morphological traits within Caenorhabditis briggsae natural isolates and mutation-accumulation (MA) lines of both C. briggsae and Caenorhabditis elegans. Substantial natural variation was discovered for most mitochondrial form and function traits measured for a set of C. briggsae isolates known to harbor mitochondrial DNA structural variation in the form of a heteroplasmic nad5 gene deletion (nad5δ) that correlates negatively with organismal fitness. Most among-isolate phenotypic variation could be accounted for by phylogeographic clade membership rather than nad5δ level. Analysis of mitochondrial-nuclear hybrid strains provided support for both mtDNA and nuclear genetic variation as drivers of natural mitochondrial phenotype variation. An MA experimental approach revealed that average levels of both ROS and nad5δ heteroplasmy evolved in remarkably linear ways in C. briggsae maintained under extreme inbreeding. In particular, among C. briggsae isolates prone to acquiring the nad5δ deletion, nad5δ level increased to a plateau of ~50% during successive generations of MA treatment. Conversely, mitochondrial ROS level increased or declined in a strain-specific fashion, which also meant that the relationship between ROS and nad5δ was strain-specific. Further, all lines generated from the isolate with the highest starting level of nad5δ heteroplasmy went extinct prior to generation 20 of MA treatment. Patterns of among-line variance in ROS level were also strain-specific but generally did not conform to the canonical pattern of increasing among-line variance expected for MA experiments. MA lines of C. elegans that had previously been subjected to whole-genome sequencing were found to vary significantly in ROS levels but not in 8-oxo-dG content. Despite a significant positive correlation between 8-oxo-dG and ROS levels, no relationship between oxidative stress measures and base substitution rate or G-to-T transversion rate was revealed. Finally, analysis of patterns of phenotypic correlation for a suite of 24 mitochondrial traits measured in C. briggsae natural isolates support a role for ΔΨM in shaping mitochondrial dynamics, but no such role for mitochondrial ROS. Further, our study suggests a novel model of mitochondrial population dynamics dependent upon cellular environmental context and with implications for mitochondrial genome integrity. This work identifies extensive natural variation and capacity for evolution in organellar traits within multicellular eukaryotic species, with a central role for δΨM in mitochondrial dynamics that may have implications for evolutionary adaptation to thermal niches.

Caenorhabditis

Mitochondrial DNA

Active oxygen

Mitochondria

Biology

Other Genetics and Genomics

Awareness of Genetic Predispositions that Increase the Risk of Breast Cancer

Huber, Carly

01 January 2021

Breast cancer is the most commonly diagnosed cancer in women in the United States and is the leading cause of cancer-related death among women worldwide. Certain demographics, such as racial/ethnic, age, and gender groups, are underrepresented in breast cancer studies. This lack of representation results in issues with creating genetic tests, as variants associated with those groups are not being detected. Furthermore, these underrepresented demographics are receiving a worse prognosis than those that are overrepresented in research. This study aimed to understand how informed the understudied racial/ethnic, gender, and age populations are regarding breast cancer and genetic testing compared to populations that have been abundantly studied, and the factors affecting the decision to receive genetic testing between gender groups. After distributing a survey to students at the University of Central Florida, the study found that females answered the knowledge-based questions more accurately than males; however, no significant differences were found between age or ethnicity groups. This is likely due to the sample consisting of university students who are more knowledgeable than the general population. The study found a negative correlation between gender and the influence of individual health concerns on receiving genetic testing and how often a breast self-exam is performed. A difference was also found between gender, age, and ethnic groups on having performed a breast self-exam. Further investigations should sample from a general population or other university populations for comparison. Also, increased education on breast cancer risks, performing a breast self-exam, and receiving genetic testing would be beneficial for early detection of breast cancer.

breast cancer

genetics

genetic

BRCA

awareness

Genetics and Genomics

Oncology

Sex-linked mental retardation without physical stigmata (Martin-Bell or Renpenning type) : a genetic and psychometric approach

Hanis, Craig L.

28 April 1977

Screening the Utah State Training School (a resident institution for the mentally retarded) for kindreds having at least two institutionalized sibs generated 54 sib groups. Of these, 20-male only sibships had histories compatible with sex-linked mental retardation without physical stigmata (Martin-Bell or Renpenning type). Affected males had no characteristic physical stigmata (an appreciable number did have speech problems and/or seizure disorders) and exhibited IQs ranging from 5 to 74 with a mean of 34.2. Obligate carrier females had a mean IQ score of 91.9 (range, 79 to 106), which is as would be predicted due to random X-inactivation. Carrier females were tested with the MMPI, and showed elevated profiles. The results also indicated that the FAM scale would differentiate between groups of carrier females and normal females and between groups of carrier females and other females who had retarded children. It is suggested that the extension of psychometric methods may be useful in the identification of high risk females. Identification of these females would then allow for accurate genetic counseling, an objective which has not yet been achieved.

Genetics and Genomics

Life Sciences

Identification of Druggable Targets in a Schwannomatosis Patient-Derived Tumor Cell Line

Allaf, Abdulrahman

01 January 2020

.

NF3

Schwannomatosis

NF

schwannomas

apoptosis

necroptosis

Genetics and Genomics

Functional and Expression Analysis of a Novel Basement Membrane Degrader in Drosophila Melanogaster

Fields, Christopher J

01 July 2016

The Srivastava Lab is focused on the identification and characterization of genes that play a role in basement membrane remodeling. Previously, we identified putative basement membrane degraders through a genetic screen. One such gene has been suggested to play a role in the maintenance of the stem cell niche in Drosophila melanogaster, but no other information about the role this gene plays in development or disease has been published. Here, data are presented from experiments utilizing Drosophila genetics and immunohistochemistry that provide important insights on the biological role of this gene. Collagenase activity was up-regulated upon overexpression of this gene, confirming it as a basement membrane degrader. Additionally, RNA in-situ hybridization experiment results showed expression in the developing imaginal discs of the 3rd instar larva tissues. Overexpression and knockdown studies further demonstrated morphological defects in a number of tissues, including the wing and the eye, and are suggestive of apoptosis. Acridine orange staining confirmed that cell death occurred when the gene was overexpressed and a cleaved caspase antibody staining indicated that process to be caspase-mediated apoptosis.

Snuts

Eye and wing development

Collagenase

Genetics and Genomics

Molecular Biology

Molecular Genetics

Mechanisms of genome regulation in human islets and their role in the pathogenesis of type 2 diabetes

van de Bunt, Gerrit Martinus

January 2014

Genome-wide association studies (GWAS) have made substantial progress in implicating genomic regions in type 2 diabetes (T2D) susceptibility. Whilst attributing causal mechanisms to loci has proved non trivial, these studies have provided insights into the genetic architecture underlying the disease. GWAS findings indicate a causal role for gene regulatory processes, and suggest that pancreatic beta-cells play a pivotal role in mediating common T2D association. Work presented in this thesis therefore sought to generate novel regulatory annotations from human islets, and to assess whether T2D-associated loci can be accurately fine-mapped using statistical approaches, with the aim of improving understanding of causal mechanisms underlying these associations through integration of the two approaches. Using small RNA sequencing in human islets and enriched beta-cell populations (both n=3) and mRNA sequencing in a large number of human islets (n=130), I increased the number of available human islet annotations. These studies identified high or islet-specific expression in many micro RNAs (miRNAs) without previously known roles in human islets. It also provided the largest study of quantitative trait loci (eQTLs) and allele-specific expression (ASE) in human islets to date, identifying significant eQTLs for 1,636 genes and significant ASE at 8,754 genes. There was enrichment of active islet chromatin, compared to other tissues, at the best eQTL variant for each gene, but also substantial sharing of significant eQTLs between islets and other tissues. Simulations were used to assess the utility of fine-mapping approaches for refining common disease-associated loci to smaller intervals or sets of variants likely to include the causal variant. The results demonstrated that fine-mapping can indeed refine these loci to sets or intervals of a size more amenable to functional follow-up or focussed intersection with high quality annotations. Furthermore, using an approximated Bayesian approach, I was able to refine twenty-one of the known common T2D-associated loci. Finally, using the newly generated annotations, I demonstrated enrichment of T2D association signal for regulatory RNA annotations (islet lncRNAs and miRNA target gene sets). I also identified examples in which these types of annotation overlap common and rare variation suggestive of a role in T2D pathogenesis. Using further islet annotations, I also uncovered potential causal mechanisms at four of the twentyone fine-mapped common T2D loci. These data therefore provide many novel islet regulatory annotations that can be intersected with T2D genetics, and provide a first example of how such an approach can lead to novel potential causal mechanisms underlying association loci.

616.4

The Molecular Evolution of Non-Coding DNA and Population Ecology of the Spiny Softshell Turtle (Apalone spinifera) in Lake Champlain

Bernacki, Lucas Edward

01 January 2015

ABSTRACT Spiny softshell turtles (Apalone spinifera) occur at the northwest limit of their range in Lake Champlain. This species, although widespread across North America, is listed as threatened in Vermont due to habitat destruction and disturbances of anthropogenic origin. The population of spiny softshell turtles in Lake Champlain is isolated from other North American populations and is considered as an independent management unit. Efforts to obtain information on the biology of spiny softshell turtles in Lake Champlain precede 1936 with conservation measures being initiated in 1987. Methods of studying spiny softshell turtles in Lake Champlain have included direct observation, mark-recapture, nest beach monitoring, winter diving, and radio telemetry. Each of these approaches has provided some information to the sum of what is known about A. spinifera in Lake Champlain. For example major nesting beaches, hibernacula, and home range size have been determined. Currently spiny softshell turtles primarily inhabit two areas within Lake Champlain, Missisquoi Bay and the mouth of the Lamoille River. However, the population structure and gene flow between spiny softshell turtles inhabiting the Lamoille and Missisquoi regions remained unknown. A GIS model was created and tested in order to identify additional nesting beaches used by spiny softshell turtles along the Vermont shores of Lake Champlain. Although some additional small potential nesting beaches were found, no additional major nesting sites were found. The GIS model identified the mouth of the Winooski River (the site of a historical population) as potentially suitable nesting habitat; however, no evidence of spiny softshell turtle nesting was found at this site. A series of methods developed for collecting molecular and population genetic data about spiny softshell turtles in Lake Champlain are described, including techniques for DNA extraction of various tissue types and the design of new primers for PCR amplification and sequencing of the mitochondrial control region (mtD-loop). Techniques for circumventing problems associated with DNA sequence alignment in regions of a variable numbers of tandem repeats (VNTRs) and the presence of heteroplasmy within some individuals are also described. The mtD-loop was found to be a suitable marker to assess the genetic structure of the Lake Champlain population of spiny softshell turtles. No significant genetic sub-structuring was found (FST=0.082, p=0.223) and an indirect estimate of the migration rate between Lamoille and Missisquoi regions of Lake Champlain was high (Nm>5.576). In addition to consideration of A. spinifera in Lake Champlain, the mtD-loop was modeled across 46 species in 14 families of extant turtles. The primary structure was obtained from DNA sequences accessed from GenBank and secondary structures of the mtD-loop were inferred, (from thermal stabilities) using the program Mfold, for each superfamiliy of turtles. Both primary and secondary structures were found to be highly variable across the order of turtles; however, the inclusion of an AT-rich fold (secondary structure) near the 3' terminus of the mtD-loop was common across all turtle families considered. The Cryptodira showed conservation in the primary structure at regular conserved sequence blocks (CSBs), but the Pluerodira displayed little conservation in the primary structure of the mtD-loop. Overall, greater conservation in secondary structure than primary structure was observed in turtle mtD-loop. The AT-rich secondary structural element near the 3' terminus of the mtD-loop may be conserved across turtles due to it serving a functional role during mtDNA transcription.

Control Region

D-loop

DNA

GIS

Mitochondrial

Turtle

Biology

Genetics and Genomics

Natural Resources and Conservation

Mechanisms and Dynamics of Oxidative DNA Damage Repair in Nucleosomes

Cannan, Wendy J.

01 January 2016

DNA provides the blueprint for cell function and growth, as well as ensuring continuity from one cell generation to the next. In order to compact, protect, and regulate this vital information, DNA is packaged by histone proteins into nucleosomes, which are the fundamental subunits of chromatin. Reactive oxygen species, generated by both endogenous and exogenous agents, can react with DNA, altering base chemistry and generating DNA strand breaks. Left unrepaired, these oxidation products can result in mutations and/or cell death. The Base Excision Repair (BER) pathway exists to deal with damaged bases and single-stranded DNA breaks. However, the packaging of DNA into chromatin provides roadblocks to repair. Damaged DNA bases may be buried within nucleosomes, where they are inaccessible to repair enzymes and other DNA binding proteins. Previous in vitro studies by our lab have demonstrated that BER enzymes can function within this challenging environment, albeit in a reduced capacity. Exposure to ionizing radiation often results in multiple, clustered oxidative lesions. Near-simultaneous BER of two lesions located on opposing strands within a single helical turn of DNA of one another creates multiple DNA single-strand break intermediates. This, in turn, may create a potentially lethal double-strand break (DSB) that can no longer be repaired by BER. To determine if chromatin offers protection from this phenomenon, we incubated DNA glycosylases with nucleosomes containing clustered damages in an attempt to generate DSBs. We discovered that nucleosomes offer substantial protection from inadvertent DSB formation. Steric hindrance by the histone core in the nucleosome was a major factor in restricting DSB formation. As well, lesions positioned very close to one another were refractory to processing, with one lesion blocking or disrupting access to the second site. The nucleosome itself appears to remain intact during DSB formation, and in some cases, no DNA is released from the histones. Taken together, these results suggest that in vivo, DSBs generated by BER occur primarily in regions of the genome associated with elevated rates of nucleosome turnover or remodeling, and in the short linker DNA segments that lie between adjacent nucleosomes. DNA ligase IIIα (LigIIIα) catalyzes the final step in BER. In order to facilitate repair, DNA ligase must completely encircle the DNA helix. Thus, DNA ligase must at least transiently disrupt histone-DNA contacts. To determine how LigIIIα functions in nucleosomes, given this restraint, we incubated the enzyme with nick-containing nucleosomes. We found that a nick located further within the nucleosome was ligated at a lower rate than one located closer to the edge. This indicated that LigIIIα must wait for DNA to spontaneously, transiently unwrap from the histone octamer to expose the nick for recognition. Remarkably, the disruption that must occur for ligation is both limited and transient: the nucleosome remains resistant to enzymatic digest before and during ligation, and reforms completely once LigIIIα dissociates.

base exicison repair

chromatin

DNA damage

DNA enzymes

DNA repair

nucleosomes

Biochemistry

Genetics and Genomics

Molecular Biology

HIF-INDEPENDENT RESPONSES IN HYPOXIA

Padmanabha, Divya

01 January 2015

The adaptive response to hypoxia is accompanied by widespread transcriptional changes that allow for prolonged survival in low oxygen. Many of these changes are directly regulated by the conserved hypoxia-inducible factor-1 (HIF-1) complex; however, even in its absence, many oxygen-sensitive transcripts in Caenorhabditis elegans are appropriately regulated in hypoxia. To identify mediators of these non-HIF-dependent responses, I established a hif-1 mutant reporter line that expresses GFP in hypoxia or when worms are treated with the hypoxia mimetic cobalt chloride (cobalt chloride). The reporter is selective and HIF-independent, in that it remains insensitive to a number of cellular stresses, but is unaffected by mutation of the prolyl hydroxylase egl-9, suggesting that the regulators of this response pathway are different from those controlling the HIF pathway. I used the HIF-independent reporter to screen a transcription factor RNAi library and identified genes that are required for hypoxia sensitive and cobalt chloride-induced GFP expression. Three mediators of the HIF-independent response zinc finger protein BLMP-1, chromatin remodeling factor LIN-40, and T-box transcription factor TBX-38 were isolated as mediators of the HIF-independent response. First, we show that mutation of blmp-1 renders animals sensitive to hypoxic exposure and that blmp-1 it is required for appropriate hypoxic-induced expression of HIF-independent transcripts. Further, we demonstrate that BLMP-1 is necessary for an increase of hypoxia-dependent histone acetylation within the promoter of a non-HIF-dependent hypoxia response gene. Additionally, we explore BLMP-1’s role in two hypoxia-regulated physiological processes namely unfolded protein response and collagen formation. We also briefly investigate the role of LIN-40 in the hypoxia response.

hypoxia

C.elegans

BLMP-1

Genetics and Genomics

Molecular Biology

MYSTERIES OF THE TRYPANOSOMATID MAXICIRCLES: CHARACTERIZATION OF THE MAXICIRCLE GENOMES AND THE EVOLUTION OF RNA EDITING IN THE ORDER KINETOPLASTIDA

Iyengar, Preethi Ranganathan

01 January 2015

The trypanosomatid protists belonging to Order Kinetoplastida are some of the most successful parasites ever known to mankind. Their extreme physiological diversity and adaptability to different environmental conditions and host systems make them some of the most widespread parasites, causing deadly diseases in humans and other vertebrates. This project focuses on their unique mitochondrion, called the kinetoplast, and more specifically involves the characterization of a part of their mitochondrial DNA (also called kinetoplast DNA or kDNA), the maxicircles, which are functional homologs of eukaryotic mitochondrial DNA in the kinetoplastid protists. We have sequenced and characterized the maxicircle genomes of 20 new trypanosomatids and compared them with 8 previously published maxicircle genomes of other trypanosomatids. Transcripts of ~13 of the 20 total genes in these maxicircles undergo post-transcriptional modifications involving the insertion and deletion of U residues at precise sites, to yield the final, fully-edited, translatable mRNA. We have deciphered the diverse patterns and extents of RNA editing of each edited gene in the maxicircle of each organism, and inferred the sequences of the putative fully edited mitochondrial transcripts and proteins. Using a binary value - based strategy (1/0), we quantified the RNA editing in all these trypanosomatids and estimated the evolution of RNA editing in the group. Additionally, we conducted phylogenetic analyses using a subset of unedited maxicircle genes to predict the relationships between the various trypanosomatids in this project, and compared them to the previously published nuclear gene-based phylogenies. For convenience of analysis, the 28 total trypanosomatids in this work were divided into two groups: the first group consisting of the endosymbiont-bearing and related insect trypanosomatids, which constitute the first half of the project, and the second group consisting of trypanosomatids of the Trypanosoma genus, including T. cruzi-related and unrelated parasites, constituting the latter half of the project. In summary, most of the trypanosomatid maxicircles showed a syntenic panel of 20 protein-coding genes (excluding any guide RNA genes), beginning with the mitochondrial ribosomal genes and ending with the gene encoding NADH dehydrogenase-5. Although some genes were partially or completely absent in the maxcircles of some species, the remaining genes were completely syntenic. The total number of genes edited and their editing patterns varied considerably among the first group of insect trypanosomatids, but were remarkably similar in the second group of the Trypanosoma genus. On a broad scale, the mitochondrial phylogeny reflects the nuclear phylogeny for these trypanosomatids, except within the T. cruzi population. Similarly, RNA editing appears to have evolved in parallel with the nuclear genes, although subtle differences are again noticeable within the T. cruzi family.

maxicircle

trypanosomatid

kinetoplast

endosymbiont

RNA editing

evolution

Bioinformatics

Biology

Computational Biology

Genetics and Genomics

Microbiology

Molecular Biology