Using genomics and transcriptomics as a tool to understand unique phenotypes of hemipteran insects that are relevant to agriculture and public health

Walt, Hunter Kelly

13 December 2024

In the past couple of decades, advances in genomic sequencing technology have caused an unprecedented increase in biological data. Because of the quantity and size of these datasets, the need for biologists with computational expertise also increased, and using these large genomic datasets has revolutionized the way we can answer biological questions. In this dissertation, I apply genomic and transcriptomic data to answer questions about insects of the order Hemiptera that are relevant to agriculture and public health. My dissertation mainly focuses on stink bugs (Hemiptera: Pentatomidae), many of which are agricultural pests, and bed bugs (Hemiptera: Cimicidae), which are blood-sucking insects of public health concern. Using the genome and salivary transcriptome of a soybean pest, we found evidence that retention of ancestral genes instead of genomic innovations explains its heightened ability to degrade soybean tissues compared to other stink bugs. Our investigation of this stink bug’s salivary transcriptome led to an additional discovery that a horizontally transferred gene present in phytophagous stink bugs and the seed bugs may help them digest seed tissues during feeding. Next, we investigated bed bugs which are interesting because they feed on human blood but have never been linked to pathogen transmission. To survey the understudied viral diversity within bed bugs, we sequenced the metatranscriptomes of a worldwide sample of individual bed bugs and discovered three novel bed bug viruses, while also detecting two previously known bed bug viruses. Notably, we did not detect any human viruses. Finally, we exposed bed bugs to diverse immune challenges and measured their transcriptomic responses. We found that bed bugs express canonical immune effectors when exposed to an entomopathogen and environmental bacteria, but not a human pathogen.

Biology

Life Sciences

The evolution of LOL, the secondary metabolite gene cluster for insecticidal loline alkaloids in fungal endophytes of grasses.

Kutil, Brandi Lynn

15 May 2009

LOL is a novel secondary metabolite gene cluster associated with the production of loline alkaloids (saturated 1-aminopyrrolizidine alkaloids with an oxygen bridge) exclusively in closely related grass-endophyte species in the genera Epichloë and Neotyphodium. In this study I characterize the LOL cluster in E. festucae, including the presentation of sequence corresponding to 10 individual lol genes as well as defining the boundaries of the cluster and evaluation of the genomic DNA region flanking LOL in E. festucae. In addition to characterizing the LOL cluster in E. festucae, I present LOL sequence from two additional species, Neotyphodium coenophialum and Neotyphodium sp. PauTG-1. Together with two recently published LOL clusters from N. uncinatum, these data allow for a powerful phylogenetic comparison of five clusters from four closely related species. There is a high degree of microsynteny (conserved gene order and orientation) among the five LOL clusters, allowing us to predict potential transcriptional co-regulatory binding motifs in lol promoter regions. The relatedness of LOL clusters is especially interesting in light of the history of interspecific hybridizations that generated the asexual, Neotyphodium lineages. In fact, three of the clusters appear to have been introduced to different Neotyphodium species by the same ancestral Epichloë species, for which present day isolates are no longer able to produce lolines. To address the evolutionary origins of the cluster we have investigated the phylogenetic relationships of particular lol ORFs to their paralogous primary metabolism genes (and gene families) from endophytes, other fungi and even other kingdoms. I present extensive evidence that at least two individual lol genes have evolved from primary metabolism genes within the fungal ancestors of endophytes, rather than being introduced via horizontal gene transfer. I also present complementation studies in Neurospora crassa exploring the functional divergence of one lol gene from its primary metabolism paralog. While it is clear that these insecticidal compounds should convey a selective advantage to the fungus and its host, thus explaining preservation of the trait, this analysis provides an exploration into the evolutionary origin and maintenance of the genes that comprise the LOL and the cluster itself.

Gene family evolution

Epichloe festucae Neotyphodium spp.

Neurospora crassa spe-1

ornithine decarboxylase

ortholog/paralog gene tree

PhyloCon motif

The evolution of LOL, the secondary metabolite gene cluster for insecticidal loline alkaloids in fungal endophytes of grasses.

Kutil, Brandi Lynn

15 May 2009

LOL is a novel secondary metabolite gene cluster associated with the production of loline alkaloids (saturated 1-aminopyrrolizidine alkaloids with an oxygen bridge) exclusively in closely related grass-endophyte species in the genera Epichloë and Neotyphodium. In this study I characterize the LOL cluster in E. festucae, including the presentation of sequence corresponding to 10 individual lol genes as well as defining the boundaries of the cluster and evaluation of the genomic DNA region flanking LOL in E. festucae. In addition to characterizing the LOL cluster in E. festucae, I present LOL sequence from two additional species, Neotyphodium coenophialum and Neotyphodium sp. PauTG-1. Together with two recently published LOL clusters from N. uncinatum, these data allow for a powerful phylogenetic comparison of five clusters from four closely related species. There is a high degree of microsynteny (conserved gene order and orientation) among the five LOL clusters, allowing us to predict potential transcriptional co-regulatory binding motifs in lol promoter regions. The relatedness of LOL clusters is especially interesting in light of the history of interspecific hybridizations that generated the asexual, Neotyphodium lineages. In fact, three of the clusters appear to have been introduced to different Neotyphodium species by the same ancestral Epichloë species, for which present day isolates are no longer able to produce lolines. To address the evolutionary origins of the cluster we have investigated the phylogenetic relationships of particular lol ORFs to their paralogous primary metabolism genes (and gene families) from endophytes, other fungi and even other kingdoms. I present extensive evidence that at least two individual lol genes have evolved from primary metabolism genes within the fungal ancestors of endophytes, rather than being introduced via horizontal gene transfer. I also present complementation studies in Neurospora crassa exploring the functional divergence of one lol gene from its primary metabolism paralog. While it is clear that these insecticidal compounds should convey a selective advantage to the fungus and its host, thus explaining preservation of the trait, this analysis provides an exploration into the evolutionary origin and maintenance of the genes that comprise the LOL and the cluster itself.

Gene family evolution

Epichloe festucae Neotyphodium spp.

Neurospora crassa spe-1

ornithine decarboxylase

ortholog/paralog gene tree

PhyloCon motif

Primates, poison, and cytochrome P450: Evolutionary dynamism of the CYP1-3 gene families within the primate order

Chaney, Morgan Edward

24 April 2023

No description available.

Biology

Molecular Biology

Pharmacology

Toxicology

Zoology

molecular primatology

gene family evolution

bamboo lemurs

prolemur

hapalemur

plant secondary metabolites

xenobiotic

The Evolution of Fungal Pectinases in Glycosyl Hydrolase Family 28 and Their Association with Ecological Strategy

Sprockett, Daniel David

02 December 2009

No description available.

Bioinformatics

Biology

Ecology

Genetics

Microbiology

Molecular Biology

gene family evolution

gene birth-and-death

pectinase

glycosyl hydrolase family 28

fungi

biotroph

necrotroph

PGIP

polygalacturonase

Venomics of Sea Anemones: A Bioinformatic Approach to Tissue Specific Venom Composition and Toxin Gene Family Evolution.

Macrander, Jason C.

26 September 2016

No description available.

Zoology

Animals

Bioinformatics

Biology

Evolution and Development

Toxicology

Venom

Sea Anemones

Gene Family Evolution

Transcriptomics

Actinoporins

Sodium Channel Toxins

Potassium Channel Toxins

Evolution of Vertebrate Endocrine and Neuronal Gene Families : Focus on Pituitary and Retina

Ocampo Daza, Daniel

January 2013

The duplication of genes followed by selection is perhaps the most prominent way in which molecular biological systems gain multiplicity, diversity and functional complexity in evolution. Whole genome duplications (WGDs) therefore have the potential of generating an extraordinary amount of evolutionary innovation. It is now accepted that the vertebrate lineage has gone through two rounds of WGD in its early stages, after the divergence of invertebrate chordates and before the emergence of jawed vertebrates. These basal vertebrate WGDs are called 2R for two rounds of whole genome duplication. An additional WGD called 3R occurred early in the evolution of teleost fishes, before the radiation of this species-rich group. This thesis describes the evolution of several endocrine and neuronal gene families in relation to the vertebrate WGDs, through a comparative genomic approach including both phylogenetic analyses and chromosomal location data across a wide range of vertebrate taxa. These results show that numerous endocrine gene families have expanded in 2R and in several cases also in 3R. These include the gene families of oxytocin and vasopressin receptors (OT/VP-R), somatostatin receptors (SSTR) and insulin-like growth factor binding proteins (IGFBP). For the OT/VP-R and SSTR families, previously undescribed subtypes were identified. The protein hormone family that includes growth hormone (GH), prolactin (PRL) and somatolactin (SL) acquired a new PRL gene in 2R, however the origins of GH, PRL and SL likely predate 2R. The corresponding family of receptors diversified during different time periods through a combination of local duplications and 3R. Neuronal gene families of the visual system have also expanded in 2R and 3R. The results presented here demonstrate that the vertebrate repertoire of visual opsin genes arose in 2R as part of chromosomal blocks that also include the OT/VP-R genes. The gene families including the transducin alpha, beta and gamma subunits also arose in 2R, hinting at the importance of these events in the diversification and specialization of phototransduction cascades for rods and cones. Thus, the whole genome duplications have been important contributors to the evolution of both vision and endocrine regulation in the vertebrates.

phylogenetics

evolution

molecular evolution

gene family evolution

genome duplication

gene duplication

oxytocin receptor

vasopressin receptor

visual opsin

transducin

growth hormone

prolactin

somatolactin

growth hormone receptor

prolactin receptor

somatostatin receptor

SSTR

IGFBP

evolution

molekylär evolution

fylogeni