Hessian fly associated microbes: dynamics, transmission and essentiality

Bansal, Raman

January 1900

Doctor of Philosophy / Department of Entomology / Ming-Shun Chen / John C. Reese / Keeping in view the important roles of bacteria in almost every aspect of insect’s life, the current study is the first systemic and intensive work on microbes associated with Hessian fly, a serious pest of wheat crop. A whole body analysis of Hessian fly larvae, pupae, or adults suggested that a remarkable diversity of bacteria is associated with different stages of the insect life cycle. The overriding detection of genera Acinetobacter and Enterobacter throughout the life cycle of Hessian fly suggested a stable and intimate relationship with the insect host. Adult Hessian flies have the most dissimilar bacterial composition from other stages with Bacillus as the most dominant genus. Analysis of 5778 high quality sequence reads obtained from larval gut estimated 187, 142, and 262 operational taxonomic units at 3% distance level from the 1st, 2nd, and 3rd instar respectively. Pseudomonas was the most dominant genus found in the gut of all three instars. The 3rd instar larval gut had the most diverse bacterial composition including genera Stenotrophomonas, Pantoea, Enterobacter, Ensifer, and Achromobacter. The transovarial transmission of major bacterial groups provided evidence of their intimate relationship with the Hessian fly. The Hessian fly is known to manipulate wheat plants to its own advantage. This study demonstrated that the combination of a decrease in carbon compounds and an increase in nitrogen compounds in the feeding tissues of Hessian fly-infested plants results in a C/N ratio of 17:1, nearly 2.5 times less than the C/N ratio (42:1) observed in control plants. We propose that bacteria associated with Hessian fly perform nitrogen fixation in the infested wheat, which was responsible for shifting the C/N ratio. The following findings made in the current study i.e. the presence of bacteria encoding nitrogenase (nifH) genes both in Hessian fly and infested wheat, exclusive expression of nifH in infested wheat, presence of diverse bacteria (including the nitrogen fixing genera) in the Hessian fly larvae, presence of similar bacterial microbiota in Hessian fly larvae and at the feeding site tissues in the infested wheat, and reduction in survival of Hessian fly larvae due to loss of bacteria are consistent with this hypothesis. The reduction in Hessian fly longevity after the loss of Alphaproteobacteria in first instar larvae, highest proportion of Alphaproteobacteria in insects surviving after the antibiotic treatments and the nitrogen fixation ability of associated Alphaproteobacteria strongly implies that Alphaproteobacteria are critical for the survival of Hessian fly larvae. This study provides a foundation for future studies to elucidate the role of associated microbes on Hessian fly virulence and biology. A better understanding of Hessian fly-microbe interactions may lead to new strategies to control this pest.

Hessian Fly

Bacteria

Wheat

Microbiota

Symbiosis

Nitrogenase

Biology, Entomology (0353)

Biology, Microbiology (0410)

Biology, Molecular (0307)

Evaluation of targetron based mutagenesis in Ehrlichia chaffeensis

Gong, Shanzhong

January 1900

Master of Science / Department of Diagnostic Medicine/Pathobiology / Roman Reddy R. Ganta / Ehrlichia chaffeensis is an emerging tick-borne rickettsial pathogen that causes infection in people and several vertebrate animals. One of the striking features of E. chaffeensis infection is the prolonged persistence in its vertebrate and tick hosts. The mechanism of persistent infection and the reasons for the host immune system failure to clear the infection are not well understood. One hypothesis is that differential gene expression serves as an important adaptive mechanism used by E. chaffeensis in support of its continued survival in both tick and vertebrate hosts. One way to test this hypothesis is by performing mutational analysis. However, the methods for introducing mutations in this pathogen have not yet been documented and are challenging, possibly due to its obligate, intraphagosomal growth requirement. Recently, a novel gene mutation method called ‘TargeTron Gene Knockout System’ that is based on the modified group II intron insertion strategy has been developed. This method appears to be effective in creating mutations in a wide range of gram positive and gram negative bacterial organisms. The group II intron can be programmed for insertion into virtually any desired DNA target with possibly high frequency and specificity. In this study, I focus on creating mutations in E. chaffeensis using the TargeTron gene knockout system. I prepared modified group II intron constructs retargeting for insertion into three E. chaffeensis genes: Ech_0126 (a transcriptionally silent gene), macrophage-specific expressed gene (p28-Omp 19, Ech_1143) and tick cell-specific expressed gene (p28-Omp 14, Ech_1136). In support of driving the expression of the modified group II introns in E. chaffeensis, the pathogen- specific high-expressing gene promoter (tuf) was inserted upstream to the transcription start site. In addition, a chloramphenicol acetyltransferase gene with E. chaffeensis rpsl promoter was introduced for use as a selection marker. The constructs were then evaluated by transforming into E. chaffeensis. Transformants with mutations, introduced in two of the three genes (Ech_0126 and Ech_1143), were identified by PCR and Southern blot methods. Although the mutants are detectable for up to 48 hours, establishment of stable transformants remains to be challenging. The outcomes of this project will have important implications in defining the pathogenesis of E. chaffeensis, particularly to assess the differences in the organism in tick and vertebrate hosts.

Ehrlichia chaffeensis

Targetron

Agriculture, Animal Pathology (0476)

Biology, Microbiology (0410)

Biology, Molecular (0307)

Insights into the structure and function of the aggregate-reactivating molecular chaperone CLPB

Nagy, Maria

January 1900

Doctor of Philosophy / Department of Biochemistry / Michal Zolkiewski / ClpB is a bacterial heat-shock protein that disaggregates and reactivates strongly aggregated proteins in cooperation with the DnaK chaperone system. ClpB contains two ATP-binding AAA+ modules, a linker coiled-coil domain, and a highly mobile N-terminal domain. It forms ring-shaped hexamers in a nucleotide-dependent manner. The unique aggregation reversing chaperone activity of ClpB involves ATP-dependent translocation of substrates through the central channel in the ClpB ring. The initial events of aggregate recognition and the events preceding the translocation step are poorly understood. In addition to the full-length ClpB95, a truncated isoform ClpB80, that is missing the whole N-terminal domain, is also produced in vivo. Various aspects of the structure and function of ClpB were addressed in this work. The thermodynamic stability of ClpB in its monomeric and oligomeric forms, as well as the nucleotide-induced conformational changes in ClpB were investigated by fluorescence spectroscopy. Equilibrium urea-induced unfolding showed that two structural domains-the small domain of the C-terminal AAA+ module and the coiled-coil domain-were destabilized in the oligomeric form of ClpB, which indicates that only those domains change their conformation or interactions during formation of the ClpB rings. Several locations of Trp-fluorescence probes were also found to respond to nucleotide binding. The biological role of the two naturally-occurring ClpB isoforms was also investigated. We discovered that ClpB achieves optimum chaperone activity by synergistic cooperation of the two isoforms that form hetero-oligomers. We found that ClpB95/ClpB80 hetero-oligomers form preferentially at low protein concentration with higher affinity than homo-oligomers of ClpB95. Moreover, hetero-oligomers bind to aggregated substrates with a similar efficiency as homo-oligomers of ClpB95, do not show enhanced ATPase activity over that of the homo-oligomers, but display a strongly stimulated chaperone activity during the reactivation of aggregated proteins. We propose that extraction of single polypeptides from aggregates and their delivery to the ClpB channel for translocation is the rate-limiting step in aggregate reactivation and that step is supported by the mobility of the N-terminal domain of ClpB. We conclude that the enhancement of the chaperone activity of the hetero-oligomers is linked to an enhancement of mobility of the N-terminal domains.

Protein folding

Protein structure

Protein aggregation

AAA+ ATPase

Molecular chaperone

Biology, Molecular (0307)

Chemistry, Biochemistry (0487)

The Plant Transcriptome and Its Response to Envrionmental Stimuli

Wilkins, Olivia

02 September 2010

The relationship between an organism’s genome, developmental stage, and environment is complex. The aim of the research presented herein was to provide experimental evidence to contribute to the annotation of the P. trichocarpa genome and to test two major hypotheses addressing the interaction between drought and time of day in A. thaliana and in two hybrid Populus clones. In order to generate data to address these aims, three separate experiments were undertaken. First, all members of the R2R3-MYB family of transcription factors in the P. trichocarpa genome were characterised by phylogenetic analysis and their transcript accumulation patterns across a range of tissues and organs were assessed using whole genome poplar microarrays. Results of this analysis indicated that expansion and diversification of the R2R3-MYB family may have contributed to phenotypic innovation in the Populus lineage. Second, drought-responsive transcriptome adjustments of two hybrid poplar clones, DN34 (P. deltoides X P. nigra) and NM6 (P. nigra X P. maxiomowiczii) were assessed for time-of-day and genotype dependent patterns. For each genotype, each of four time points was characterised by discrete sets of drought-responsive genes. Furthermore, while a number of genes were identified that were responsive to drought in both genotypes, a much larger number of genotype-dependent, drought-responsive transcriptome changes were detected. Finally, the drought-responsive transcriptome adjustments A. thaliana plants were assessed for time-of-day dependent accumulation patterns. Results of this analysis indicate that time-of-day-dependent differences in the drought response were manifest as changes of different magnitudes for a conserved set of genes across the four time points measured. These results emphasise the complex interplay of a plant’s genome, developmental stage, and environment in shaping the observed transcriptome.

Drought

R2R3-MYB

Diurnal

Arabidopsis

Hybrid poplar

Populus

Genomics

Microarray

Botany 0309

Molecular 0307

Investigating the Integration of Alternative Splicing and Transcriptional Regulation in Mammalian Gene Expression

Ip, Yuen Yan

31 August 2011

Alternative splicing functions to generate proteomic diversity and to regulate gene expression in higher eukaryotes. Genome-wide analyses suggest that alternative splicing and transcription typically regulate different gene sets to achieve cell- and tissue-type specificity. However, within individual cell-types, most alternative splicing events occur co-transcriptionally and are impacted by the transcriptional machinery. Despite many focused studies on co-transcriptional regulation of alternative splicing, its mechanisms and functions in regulation of gene expression are still poorly understood. To investigate relationships between transcription and alternative splicing, I performed microarray profiling of alternative splicing and transcript levels during activation of a T cell line. This experiment revealed that different sets of genes and associated functional categories are regulated by alternative splicing and transcription during T cell activation. I next employed inhibitors of RNA polymerase II (Pol II) elongation and microarray profiling to identify genes with coupled changes in splicing and transcript levels when transcription is impeded in activated T cell. Genes that were affected at both levels were significantly enriched in RNA binding and processing functions, and generally displayed increased alternative exon inclusion and decreased transcript levels when transcription elongation was disrupted. Similar effects were observed when transcription was driven by mutant polymerases with reduced elongation activity, and when cells were subjected to stress treatments. Many of the elongation inhibition-sensitive exons from the affected genes introduce premature termination codons into the mRNA, resulting in spliced mRNAs that are substrates of the nonsense-mediated decay pathway and further reduction in mRNA levels. ChIP-Seq experiment demonstrated that Pol II occupancy specifically increased in introns flanking the affected exons. These results provide evidence that a physiological function of transcription elongation-coupled alternative splicing regulation is to regulate the levels of RNA processing factors under conditions that reduce elongation activity, including cell stress. In summary, my thesis research has provided new insights into the integration of transcription and splicing control. While these two regulatory levels can control different gene sets during the activation of T cells, within a given cell type, they are closely coupled to control specific alternative splicing events that appear to coordinate mRNA and RNA processing factors levels.

transcription

alternative splicing

RNA polymerase II

T cell activation

Molecular 0307

The Plant Transcriptome and Its Response to Envrionmental Stimuli

Wilkins, Olivia

02 September 2010

The relationship between an organism’s genome, developmental stage, and environment is complex. The aim of the research presented herein was to provide experimental evidence to contribute to the annotation of the P. trichocarpa genome and to test two major hypotheses addressing the interaction between drought and time of day in A. thaliana and in two hybrid Populus clones. In order to generate data to address these aims, three separate experiments were undertaken. First, all members of the R2R3-MYB family of transcription factors in the P. trichocarpa genome were characterised by phylogenetic analysis and their transcript accumulation patterns across a range of tissues and organs were assessed using whole genome poplar microarrays. Results of this analysis indicated that expansion and diversification of the R2R3-MYB family may have contributed to phenotypic innovation in the Populus lineage. Second, drought-responsive transcriptome adjustments of two hybrid poplar clones, DN34 (P. deltoides X P. nigra) and NM6 (P. nigra X P. maxiomowiczii) were assessed for time-of-day and genotype dependent patterns. For each genotype, each of four time points was characterised by discrete sets of drought-responsive genes. Furthermore, while a number of genes were identified that were responsive to drought in both genotypes, a much larger number of genotype-dependent, drought-responsive transcriptome changes were detected. Finally, the drought-responsive transcriptome adjustments A. thaliana plants were assessed for time-of-day dependent accumulation patterns. Results of this analysis indicate that time-of-day-dependent differences in the drought response were manifest as changes of different magnitudes for a conserved set of genes across the four time points measured. These results emphasise the complex interplay of a plant’s genome, developmental stage, and environment in shaping the observed transcriptome.

Drought

R2R3-MYB

Diurnal

Arabidopsis

Hybrid poplar

Populus

Genomics

Microarray

Botany 0309

Molecular 0307

Investigating the Integration of Alternative Splicing and Transcriptional Regulation in Mammalian Gene Expression

Ip, Yuen Yan

31 August 2011

Alternative splicing functions to generate proteomic diversity and to regulate gene expression in higher eukaryotes. Genome-wide analyses suggest that alternative splicing and transcription typically regulate different gene sets to achieve cell- and tissue-type specificity. However, within individual cell-types, most alternative splicing events occur co-transcriptionally and are impacted by the transcriptional machinery. Despite many focused studies on co-transcriptional regulation of alternative splicing, its mechanisms and functions in regulation of gene expression are still poorly understood. To investigate relationships between transcription and alternative splicing, I performed microarray profiling of alternative splicing and transcript levels during activation of a T cell line. This experiment revealed that different sets of genes and associated functional categories are regulated by alternative splicing and transcription during T cell activation. I next employed inhibitors of RNA polymerase II (Pol II) elongation and microarray profiling to identify genes with coupled changes in splicing and transcript levels when transcription is impeded in activated T cell. Genes that were affected at both levels were significantly enriched in RNA binding and processing functions, and generally displayed increased alternative exon inclusion and decreased transcript levels when transcription elongation was disrupted. Similar effects were observed when transcription was driven by mutant polymerases with reduced elongation activity, and when cells were subjected to stress treatments. Many of the elongation inhibition-sensitive exons from the affected genes introduce premature termination codons into the mRNA, resulting in spliced mRNAs that are substrates of the nonsense-mediated decay pathway and further reduction in mRNA levels. ChIP-Seq experiment demonstrated that Pol II occupancy specifically increased in introns flanking the affected exons. These results provide evidence that a physiological function of transcription elongation-coupled alternative splicing regulation is to regulate the levels of RNA processing factors under conditions that reduce elongation activity, including cell stress. In summary, my thesis research has provided new insights into the integration of transcription and splicing control. While these two regulatory levels can control different gene sets during the activation of T cells, within a given cell type, they are closely coupled to control specific alternative splicing events that appear to coordinate mRNA and RNA processing factors levels.

transcription

alternative splicing

RNA polymerase II

T cell activation

Molecular 0307

Molecular insights into arabidopsis response to Myzus persicae sulzer (green peach aphid)

Pegadaraju, Venkatramana

January 1900

Doctor of Philosophy / Department of Biology / Jyoti Shah / Phloem-feeding insects like aphids feed on a variety of crop plants and limit plant productivity. In addition they are vectors for important plant viruses. Efforts to enhance plant resistance to aphids have been hampered by lack of sufficient understanding of mechanisms of plant defense against aphids. I have utilized a plant-aphid system consisting of the model plant Arabidopsis thaliana and the generalist aphid, Myzus persicae Sulzer (green peach aphid [GPA]), to study plant response to aphids. These studies have demonstrated an important role of premature leaf senescence in controlling aphid growth in Arabidopsis. Molecular and physiological studies suggest that the Arabidopsis PAD4 (PHYTOALEXIN DEFICIENT 4) gene modulates the GPA feeding-induced senescence process. Furthermore, in comparison to the wild type plants, GPA growth was higher on pad4 mutant plants, suggesting an important role for PAD4 in plant defense against GPA. In contrast, constitutive expression of PAD4 in transgenic Arabidopsis enhanced basal resistance against GPA. Unlike its involvement in plant defense against pathogens, the role of PAD4 in Arabidopsis resistance to GPA is independent of its involvement in phytoalexin biosynthesis and of its interaction with EDS1, a PAD4-interacting protein. Instead, the heightened resistance to GPA in these PAD4 constitutively expressing plants was associated with the rapid activation of leaf senescence. The association of premature leaf senescence in basal defense against GPA is supported by our observation that in comparison to the wild type plant, GPA growth was restricted on the Arabidopsis hypersenescence mutants, ssi2 and cpr5. Gene expression studies suggested some overlap between plant responses to pathogens and aphids, for example, activation of genes associated with the salicylic acid (SA) signaling pathway. However, the characterization of aphid performance on Arabidopsis SA biosynthesis and signaling mutants have ruled out the involvement of SA signaling in controlling aphid growth.

Senescence

Phytoalexin

Arabidopsis

Green peach aphid

Microarray

Cell death

Biology, Molecular (0307)

Cloning and characterization of the wheat domestication gene, Q

Simons, Kristin Jean

January 1900

Doctor of Philosophy / Department of Plant Pathology / Justin D. Faris / Bikram S. Gill / The Q gene is largely responsible for the widespread cultivation of durum and common wheat because it confers the square spike phenotype and the free-threshing character. It also pleiotropically influences many other domestication related traits such as glume shape, glume tenacity, rachis fragility, spike length, plant height, and spike emergence time. The objectives of this research were to confirm or reject the hypothesis that a candidate AP2-like gene is Q, confirm the dosage and pleiotropic effects attributed to Q, and begin defining the differences between the Q and q alleles. The identity of the Q gene was verified by analysis of knockout mutants and found to have a high degree of similarity to members of the AP2 family of transcription factors. Southern analysis of multiple Triticum taxa containing either Q or q indicated that the Q locus is not composed of duplicated q alleles. Ectopic expression analysis allowed the observation of both silencing and over-expression effects of Q. Rachis fragility, glume shape, and glume tenacity mimicked the q phenotype in transgenic plants exhibiting transcriptional silencing of the transgene and the endogenous Q gene. Variation in spike compactness and plant height were directly associated with the level of transgene expression due to the dosage effects of Q. Comparisons of Q and q indicated structural differences as well as variation in the level of transcription. One amino acid difference and several base changes within the promoter were identified as possible critical differences between Q and q. Very little genetic variability was found within the sequenced Q alleles suggesting it arose only once and that q is the more primitive allele.

Wheat

Domestication

Floral morphology

APETELA2

Biology, Genetics (0369)

Biology, Molecular (0307)

Molecular characterization of severe acute respiratory syndrome (SARS) coronavirus - nucleocapsid protein

Chauhan, Vinita Singh

January 1900

Doctor of Philosophy / Department of Diagnostic Medicine/Pathobiology / Raymond R. Rowland / Severe acute respiratory syndrome (SARS) is caused by an enveloped, positive-stranded RNA virus, the SARS coronavirus (SARS-CoV). Coronaviruses along with the arteriviruses are placed in the order, Nidovirales. Even though nidovirus replication is restricted to the cytoplasm, the nucleocapsid protein (N) of several coronaviruses and arteriviruses, localize to the nucleolus during infection. Confocal microscopy of N protein localization in Vero cells infected with the SARS-CoV or transfected with the SARS-CoV N gene failed to show presence of N in the nucleoplasm or nucleolus. Recombinant N remained cytoplasmic after the addition of leptomycin B (LMB), a drug that inhibits nuclear export. SARS-CoV N possesses a unique lysine-rich domain, located between amino acids 369-389, which possesses several nuclear localization signal (NLS) and nucleolar localization signal (NoLS) motifs. A chimeric protein composed of the 369-389 peptide substituted for the NLS of equine infectious anemia virus (EIAV) Rev protein (ERev) showed no nuclear localization activity. Three negatively charged amino acids, located at positions 372, 377 and 379 in SARS-CoV N were hypothesized to play a role in the loss of nuclear targeting. Substitution of aspartic acid-372 with alanine restored nuclear localization to the chimeric protein. A full-length recombinant SARS-N protein with the alanine-372 substitution localized to the nucleus. Therefore, the presence of an aspartic acid at position 372 is sufficient to retain N in the cytoplasm The mechanistic basis for how aspartic acid-372 interrupts nuclear transport is unknown, but may lie in the electrostatic repulsion with negatively charged amino acids located within the NLS binding pocket of importin-alpha.

Severe Acute Respiratory Syndrome

Coronavirus

Nucleocapsid protein

Nuclear localization

Nuclear transport

Biology, Molecular (0307)