Metabolite analysis of Chlamydomonas reinhardtii and transcriptional engineering for biofuel production

Bajhaiya, Amit

January 2015

It has been long known that algae have the potential to produce a diverse range of metabolic products including lipid and starch, which could be utilized as a fuel feedstock. Despite the capacity of algae to synthesize and store large amounts of lipids and starch, algae are not currently a commercially viable feedstock for biofuel. The metabolite storage in algae can depend on the availability of nutrients such that nutrient starvation can boost the storage of lipid and carbohydrate. These nutrient-status-induced changes in lipid and starch are underpinned by altered expression of several metabolite-related genes. However, many aspects of fatty acid and carbohydrate biosynthesis are not well understood. Furthermore, the genetic regulators of nutrient starvation-induced carbohydrate and lipid accumulation are unknown in microalgae. Therefore, this PhD focused on screening cultivation conditions, in particular Phosphorus (P) and Nitrogen (N) limited conditions that induce metabolic changes, evaluated a rapid microalgal screening method, which was used to identify putative metabolism regulators, and characterized in detail the role of one P-starvation regulator, called PSR1 (Phosphorus starvation response 1). For establishing suitable culture conditions, the microalga Chlamydomonas reinhardtii was cultured in five different P and N-limited conditions and screened for metabolic changes using Fourier transform infrared spectroscopy (FT-IR) at different phases of growth. The FT-IR spectral changes were visualized by multivariate statistical tools such as principal component analysis (PCA) and principal component-discriminant function analysis (PC-DFA). Clear clustering based on nutrient availability and metabolic changes demonstrates the potential and sensitivity of FT-IR in screening multiple culture conditions. The potential of FT-IR was further tested by screening mutant strains of C. reinhardtii that were defective in response to nutrient starvation. Nine lines with mutation in one or more of the PSR1, SNRK2.1 or SNRK2.2 genes and a wild type were screened by FT-IR for P and N starvation-induced metabolic changes. PCA, PC-DFA and predictive partial least squares discriminant analysis (PLS-DA) of FT-IR spectra, clearly distinguished wild type from mutant strains and clustered mutants with similar genetic backgrounds, demonstrating the potential of FT-IR to detect and differentiate specific genetic traits. The changes in lipid and carbohydrate profile under nutrient stress and in the different strains were validated by biochemical analysis and liquid chromatography-mass spectrometry (LC-MS).This thesis demonstrated that PSR1 is an important regulator of neutral lipid and starch biosynthesis. Transcriptomic analysis on wild type and psr1 mutant under P-starvation was performed to identify transcripts induced by P-starvation that were mis-regulated in psr1. Mainly transcripts encoding starch and triacylglycerol enzymes were affected. To further evaluate the role of PSR1 in regulating lipid and starch metabolism, complementation of psr1 and overexpression by PSR1 was performed. The P-starvation phenotype was clearly rescued in the complementation lines, and overexpression lines showed increased expression of P homeostasis genes and increased Pi accumulation in cells, with an increase in total starch content and number of starch granules. Clear increases in expression of key starch biosynthesis genes such as soluble starch synthase (SSS1, SSS5) and starch phosphorylase (SP1) was observed, which correlated with increased starch content in the overexpression lines. A carbon shift was observed as a decrease in neutral lipid was coupled with the increase in starch content. All together these findings suggest that PSR1 is a key transcriptional regulator of global metabolism, and demonstrated successful transcriptional engineering of microalgae.

Optimizing the production of erythroid cells from human embryonic stem cells

Ma, Rui

January 2015

Red blood cell (RBC) transfusion is the major treatment for patients suffering from trauma or severe anaemias, and life-long transfusion may be needed to alleviate symptoms and maintain body functioning. However, with a relatively low portion of people are donating, shortage in blood supply is becoming a life-threatening issue in the aging society. Among attempts to identify novel sources for transfusion medicine, human pluripotent stem cells (hPSCs), including embryonic stem cells (hESCs) and induced pluripotent stem cells (hiPSCs) are currently the most promising candidate, which is capable of producing donor-independent, pathogen-free and immunologically compatible RBCs. Currently, hESC-derived erythropoiesis in vitro is considered to mimic the very primitive yolk sac haematopoiesis, indicated by a low or absent level of β globin production and incomplete enucleation. Thus these cells are not mature enough to be used in transfusion medicine. The aim of this PhD project was to overexpress a key erythroid transcription factor, Erythroid Krüppel-like factor (EKLF or KLF1) in an inducible manner to improve the maturation of hESC-derived erythroid cells. EKLF is a member of the Krüppel-like factor family, which is characterized by three C2H2 type zinc finger motifs. EKLF expression in vivo is highly restricted to erythroid cells in yolk sac, fetal liver, spleen and the bone marrow, although recently a low-level of expression was found in haematopoietic precursors. Published reports demonstrate that EKLF can 1) activate β globin expression by binding to the CACCC box in its promoter or by altering β-like globin locus chromatin structure; 2) exert a role in MEP (common progenitor for erythrocytes and megakaryocytes) stage by favouring erythroid differentiation against megakaryocyte differentiation; 3) promote enucleation by affecting the DNase II-alpha expression in the central macrophage of a fetal liver erythroblastic island; 4) act as an instructive factor for lineage commitment towards erythroid fate in HSCs. In this project, 1) We tested and evaluated a feeder-free, serum-free differentiation system for deriving erythroid cells from hESCs; 2) We constructed constitutive and inducible EKLF expression vectors and validated them in K562 cells; 3) We generated hESC lines carrying these EKLF expression vectors and assessed their effects on erythrocyte production and maturation. We found that our differentiation system was capable of generating haematopoietic progenitors (HPCs) and erythroid cells at high efficiency. Using this differentiation system, we concluded that enhanced expression of EKLF upregulated adult β globin expression selectively, without altering expressions of other globins. This finding provides hints for the development of novel approaches to “reprogramme” hESCs towards a certain fate and overexpression of EKLF in this differentiation system may be beneficial for resolving issues in future transfusion medicine.

616.1

Characterization of DNA binding of the two zinc finger domains of transcription factor zBED6

Taubert, Alexander

January 2019

The zinc finger protein, zBED6, is a transcriptional regulator of IGF2 along with hundreds of other genes relating to development and growth. Studies on the growth of commercially bred pigs discovered a single nucleotide substitution in the third intron of IGF2 which disrupts the binding of zBED6 and is responsible for the three-fold upregulation of IGF2 in skeletal muscle. The mutation is linked to decreased subcutaneous fat deposition, larger organ size, and increased skeletal muscle mass. Three different constructs of the zBED6 protein made by Björklund 2018 were expressed and purified to characterize their binding affinity, where one contained both zinc finger domains and two of the constructs contained only one zinc finger domain each. Electrophoretic mobility shift assay protocol was optimized to determine the apparent Kd (= 210 ± 31nM) for the full-length construct C13 and to determine which zinc finger domain was sensitive to the mutation in the IGF2 gene. The first zinc finger domain seems to be more specific in its binding target. Preliminary microscale thermophoresis results were highly variable, needing further optimization of the protocol in order to obtain a full binding curve. The next steps involve site directed mutagenesis of residues binding DNA to determine which interactions are the most significant and possibly crystallization studies as well.

transcription factor

zinc finger

zBED6

Structural Biology

Strukturbiologi

The transcription factor activator protein family of genes in mammary gland development and breast cancer progression

Park, Jung

01 May 2015

Breast cancer is currently the second most common form of cancer and the second leading cause of death due to cancer in the United States. Breast cancer itself is subdivided into at least four subtypes, luminal A, luminal B, HER2-enriched, and basal-like, based on genomewide molecular expression patterns. Luminal A is the most common form and typically characterized by high levels of estrogen receptor (ER). HER2-enriched cancers usually, but not always, harbor amplified copies of the HER2 oncogene. Luminal B cancers share characteristics with the luminal A and HER2-enriched subtypes. Finally, basal-like cancers are more oftentimes defined by their lack of any markers or molecular targets. Thus, they are often called triple-negative breast cancer. Recent evidence suggests that there are a number transcription factors that play critical roles in the cancer progression of these malignancies. Indeed, TFAP2C has been clearly shown to positively regulate ER in luminal A cancers. Alternatively, TFAP2A appears to play an interesting, but as of yet incompletely, understood role in basal-like cancer. There has been additional evidence that suggests TFAP2C regulates multiple members of the ErbB family of receptor tyrosine kinases. Thus, we hypothesize that the TFAP2 family of transcription factors play a critical role in breast cancer progression. More specifically, we will show that TFAP2A and TFAP2C not only regulate a few critical genes in luminal and basal-like cancer, but instead are responsible for the genomewide expression pattern of these two breast cancer subtypes. Moreover, we argue that TFAP2C's regulation of certain receptor tyrosine kinases in luminal A cancers indicates promising therapeutic targets, particularly with small molecule inhibitors that are already FDA-approved. In addition, we provide data suggesting that TFAP2C likely plays an oncogenic role in HER2-positive breast cancer, possibly through the regulation of certain members of the ErbB family of receptor tyrosine kinases, such as EGFR. To address these points, we use a combination of genetically engineered mouse models, xenografts, siRNA mediated knockdown technology, western blot, qPCR, and number of additional molecular biological techniques. These results will not only establish the family of TFAP2 family of proteins as critical regulators of cancer progression, but our findings will specify how and to what extent each subtype of breast cancer is affected by individual members of the TFAP2 family of transcription factors.

breast cancer

transcription factor

Cell Anatomy

Cell Biology

Analysis, expression profiling and characterization of hsa-miR-5698 target genes as putative dynamic network biomarkers for prostate cancer: a combined in silico and molecular approach

Lombe, Chipampe Patricia

January 2019

Philosophiae Doctor - PhD / 2018, the International Agency for Research on Cancer (IARC) estimated that prostate cancer (PCa) was the second leading cause of death in males worldwide. The number of deaths are expected to raise by 50 % in the next decade. This rise is attributed to the shortcomings of the current diagnostic, prognostic, and therapeutic biomarkers used in the management of the disease. Therefore, research into more sensitive, specific and effective biomarkers is a requirement. The use of biomarkers in PCa diagnosis and management takes advantage of the genetic alterations and abnormalities that characterise the disease. In this regard, a microRNA, hsa-miR-5698 was identified in a previous study as a differentiating biomarker between prostate adenocarcinoma and bone metastasis. Six putative translational targets (CDKN1A, CTNND1, FOXC1, LRP8, ELK1 and BIRC2) of this microRNA were discovered using in silico approaches. The aim of this study was to analyse via expression profiling and characterization, the target genes of hsa-miR-5698 in order to determine their ability to act as putative dynamic network biomarkers for PCa. The study was conducted using a combined in silico and molecular approach. The in silico part of the study investigated the putative transcriptional effects of hsa-miR-5698 on the promotors of its translational targets, the correlation between hsa-miR-5698 and mRNA expression profiles as well as the co-expression analysis, pathway analysis and prognostic ability of the target genes. A number of computational software were employed for these purposes, including, R Studio, Trident algorithm, STRING, KEGG, MEME Suite, SurvExpress and ProGgene. The molecular part of the study involved expression profiling of the genes in two PCa cell line LNCaP and PC3 via qPCR.

MicroRNA

Triplex

DNA sequence motif

Prostate cancer

Transcription factor

Manipulating Embryonic Neural Precursor Cells for Therapeutic Transplantation into a Rat Model of Neuropathic Pain

Furmanski, Orion

18 December 2009

Persons with spinal cord injury (SCI) suffer life-long consequences including paralysis, loss of involuntary bodily functions, and chronic pain. A subset of SCI patients develop neuropathic pain (NP), a chronic condition resulting from damage to the spinal cord. Hyperexcitability of spinal cord sensory neurons near damaged tissue is believed to underlie SCI-related NP. Although many therapies have been employed clinically to combat SCI-NP, few give satisfactory long-term relief. Transplantation of cells that release GABA, a molecule that inhibits neuronal activity, is being explored as an alternative to current SCI-NP therapies. My experiments made progress toward preclinical modeling of GABA cell therapy for SCI-NP. First, I sought to determine whether quisqualic acid (QUIS)-induced SCI altered responses to tonic pain stimuli or altered GABAergic neural circuitry in rats. Second, I sought to determine whether a combination of genetic and trophic manipulations could promote a GABAergic phenotype in rat embryonic neural precursor cells (NPCs) in an in vitro culture system. The results revealed that QUIS-SCI rats exhibit unusually prolonged nocifensive responses to hind paw formalin injections. There was no significant difference between QUIS-SCI and sham surgery rats in c-Fos immunolabeling of spinal cord sensory neurons after formalin-induced neuronal activity. However, immunohistochemistry revealed substantial decreases in staining for markers of GABA presynaptic vesicles in injured spinal cord tissue. NPCs were enriched for a neuronal phenotype by combining withdrawal of the growth factor FGF-2 from culture media and overexpression of the transcription factor MASH1 in transfected cells. Although glial marker expression was suppressed in NPCs by these manipulations, expression of neuronal markers none the less declined through time. MASH1-overexpressing NPCs exhibited greater clonal expansion and decreased stress-induced PDI expression after FGF-2 withdrawal as compared to naïve. In light of existing data, these results suggest that the QUIS-SCI model may be useful for testing the efficacy of GABAergic NPC transplantation to reduce neuropathic pain. MASH1 overexpression and FGF-2 withdrawal could serve as a first step toward enriching GABA in NPCs for transplantation. Although the mechanism for MASH1 cytoprotection remains unclear, MASH1 may enhance survival of NPCs grafted into the spinal cord. These experiments contributed to the preclinical basis for application of therapeutic GABAergic stem cell transplantation for NP in human SCI patients.

The Role of Sox9 in Heart Valve Development and Disease

Peacock, Jacqueline D

02 May 2011

Heart valve structures open and close during the cardiac cycle to provide unidirectional blood flow through the heart, critical for efficient cardiovascular function. Valve dysfunction results in either incomplete opening or incomplete closure of the valve. Both types of valve dysfunction decrease efficiency of blood flow, increasing the load on the myocardium and leading to secondary heart disease such as pathological hypertrophy and heart failure. There are currently no effective treatments to prevent or slow the progression of valve disease, and there are no pharmacological treatments for advanced valve disease. Although most valve disease is associated with aging, increasing evidence suggests that valve disease often has origins in development. Congenital valvuloseptal defects affect many newborns, ranging from life-threatening malformations requiring immediate repair to more subtle, often undiagnosed defects that increase susceptibility to valve disease later in life. Therefore, an improved understanding of the mechanisms of heart valve formation and maintenance of adult valves may serve as an important step in improving valve disease treatment options. In this work, the mechanisms of normal valve development and the role of Sox9 in developing and mature valves are further studied. The temporal and spatial expression of extracellular matrix genes and proteins are examined throughout normal murine valve development. Sox9 function in the processes of valve development and valve maintenance is examined using mouse models of conditional Sox9 loss-of-function. Heart valve phenotypes in mice with reduced Sox9 function are examined throughout development and in adult mice with resultant calcific valve disease. The possible causative mechanisms of calcific valve disease in mice with reduced Sox9 function are further investigated by identification of novel possible targets of Sox9 transcriptional regulation. Together these studies improve our understanding of heart valve development, characterize a model of heart valve calcification with genetic etiology, and identify and characterize novel targets of Sox9.

Sox9

transcription factor

heart valves

development

valve calcification

Regulatory Elements and Gene Expression in Primates and Diverse Human Cell-types

Sheffield, Nathan

January 2013

<p>After finishing a human genome reference sequence in 2002, the genomics community has</p><p>turned to the task of interpreting it. A primary focus is to identify and characterize not only</p><p>protein-coding genes, but all functional elements in the genome. The effort has identified</p><p>millions of regulatory elements across species and in hundreds of human cell-types. Nearly</p><p>all identified regulatory elements are found in non-coding DNA, hypothesizing a function</p><p>for previously unannotated sequence. The ability to identify regulatory DNA genome-wide</p><p>provides a new opportunity to understand gene regulation and to ask fundamental questions</p><p>in diverse areas of biology.</p><p>One such area is the aim to understand the molecular basis for phenotypic differences</p><p>between humans and other primates. These phenotypic differences are partially driven</p><p>by mutations in non-coding regulatory DNA that alter gene expression. This hypothesis</p><p>has been supported by differential gene expression analyses in general, but we have not</p><p>yet identified specific regulatory variants responsible for differences in transcription and</p><p>phenotype. I have worked to identify regulatory differences in the same cell-type isolated</p><p>from human, chimpanzee, and macaque. Most regulatory elements were conserved among</p><p>all three species, as expected based on their central role in regulating transcription. How-</p><p>ever, several hundred regulatory elements were gained or lost on the lineages leading to</p><p>modern human and chimpanzee. Species-specific regulatory elements are enriched near</p><p>differentially expressed genes, are positively correlated with increased transcription, show</p><p>evidence of branch-specific positive selection, and overlap with active chromatin marks.</p><p>ivSpecies-specific sequence differences in transcription factor motifs found within this regu-</p><p>latory DNA are linked with species-specific changes in chromatin accessibility. Together,</p><p>these indicate that species-specific regulatory elements contribute to transcriptional and</p><p>phenotypic differences among primate species.</p><p>Another fundamental function of regulatory elements is to define different cell-types in</p><p>multicellular organisms. Regulatory elements recruit transcription factors that modulate</p><p>gene expression distinctly across cell-types. In a study of 112 human cell-types, I classified</p><p>regulatory elements into clusters based on regulatory signal tissue specificity. I then used</p><p>these to uncover distinct associations between regulatory elements and promoters, CpG-</p><p>islands, conserved elements, and transcription factor motif enrichment. Motif analysis</p><p>identified known and novel transcription factor binding motifs in cell-type-specific and</p><p>ubiquitous regulatory elements. I also developed a classifier that accurately predicts cell-</p><p>type lineage based on only 43 regulatory elements and evaluated the tissue of origin for</p><p>cancer cell-types. By correlating regulatory signal and gene expression, I predicted target</p><p>genes for more than 500k regulatory elements. Finally, I introduced a web resource to</p><p>enable researchers to explore these regulatory patterns and better understand how expression</p><p>is modulated within and across human cell-types.</p><p>Regulation of gene expression is fundamental to life. This dissertation uses identified</p><p>regulatory DNA to better understand regulatory systems. In the context of either evolution-</p><p>ary or developmental biology, understanding how differences in regulatory DNA contribute</p><p>to phenotype will be central to completely understanding human biology.</p> / Dissertation

Bioinformatics

DNase hypersensitivity

Gene regulation

Primate evolution

Transcription factor binding

The Role of Activating Transcription Factor 3 (ATF3) in Chemotherapeutic Induced Cytotoxicity

St. Germain, Carly

17 May 2011

Understanding the specific mechanisms regulating chemotherapeutic drug anti-cancer activities will uncover novel strategies to enhance the efficacy of these drugs in clinical settings. Activating Transcription Factor 3 (ATF3) is a stress inducible gene whose expression has been associated with survival outcomes in cancer models. This study characterizes the chemotherapeutic drugs, cisplatin and Histone Deacetylase Inhibitor (HDACi), M344 as novel inducers of ATF3 expression. Cisplatin is a DNA damaging agent widely used in various tumour types including lung, head and neck, and ovarian carcinomas. The HDAC inhibitor, SAHA, has recently been approved as a single agent in the treatment of subcutaneous T-cell lymphoma and HDACis themselves show potential for synergistic anti-cancer effects when used in combination with established chemotherapeutic drugs, including cisplatin. This study evaluates the mechanisms by which cisplatin and HDACi induce ATF3, as well as the role ATF3 plays as a mediator of cisplatin-induced cytotoxicity and the enhanced cytotoxicity between HDACi and cisplatin in combination. In this study, we demonstrate that cytotoxic doses of cisplatin and carboplatin consistently induced ATF3 expression in a panel of human tumour derived cell lines. Characterization of this induction revealed a p53, BRCA1, and integrated stress response (ISR) independent mechanism, all previously implicated in stress mediated ATF3 induction. Analysis of MAPKinase pathway involvement in ATF3 induction by cisplatin revealed a MAPKinase dependent mechanism. Cisplatin treatment, in combination with specific inhibitors to each MAPKinase pathway (JNK, ERK and p38) resulted in decreased ATF3 induction at the protein level. MAPKinase pathway inhibition led to decreased ATF3 mRNA expression and a reduction in the cytotoxic effects of cisplatin as measured by MTT cell viability assay. In A549 lung carcinoma cells, targeting ATF3 with specific shRNAs also attenuated the cytotoxic effects of cisplatin. Similarly, ATF3 -/- MEFs were shown to be less sensitive to cisplatin induced cytotoxicity as compared with ATF3+/+ MEFs. Taken together, we identified cisplatin as a MAPKinase pathway dependent inducer of ATF3 whose expression regulates in part cisplatin’s cytotoxic effects. Furthermore, we demonstrated that the HDAC inhibitor M344 was also an inducer of ATF3 expression at the protein and mRNA level in the same human derived cancer cell lines. Combination treatment with M344 and cisplatin lead to increased induction of ATF3 compared with cisplatin alone. Utilizing the MTT cell viability assay, M344 treatment was also shown to enhance the cytotoxic effects of cisplatin in these cancer cell lines. Unlike cisplatin, the mechanism of ATF3 induction by M344 was found to be independent of MAPKinase pathways. Utilizing ATF4 heterozygote (+/-) and knock out (-/-) mouse embryonic fibroblast (MEF) M334 induction of ATF3 was shown to depend on the presence of ATF4, a known regulator of ATF3 expression as part of the ISR pathway. HDACi treatment did not affect the level of histone acetylation associated with the ATF3 promoter as determined through Chromatin immunoprecipitation (ChIP) analysis, suggesting that ATF3 induction was not a direct effect of HDACi mediated histone acetylation. We also demonstrated that ATF3 regulates the enhanced cytotoxicity of M344 in combination with cisplatin as evidenced by attenuation of cytotoxicity in shRNAs targeting ATF3 expressing cells. This study identifies the pro-apoptotic factor, ATF3 as a novel target of M344, as well as a mediator of the co-operative effects of cisplatin and M344 induced tumour cell cytotoxicity.

cisplatin

Activating Transcription Factor 3

Histone Deacetylase Inhibitor

MAPKinase pathways

Regulation of Skeletal Muscle Formation and Regeneration by the Cellular Inhibitor of Apoptosis 1 (cIAP1) Protein

Enwere, Emeka K.

01 June 2011

The inhibitor of apoptosis (IAP) proteins traditionally regulate programmed cell death by binding to and inhibiting caspases. Recent studies have uncovered a variety of alternate cellular roles for several IAP family members. The cellular inhibitor of apoptosis 1 (cIAP1) protein, for instance, regulates different axes of the NF-κB signalling pathway. Given the extensive functions of NF-κB signalling in muscle differentiation and regeneration, I asked if cIAP1 also plays critical roles in skeletal muscle myogenesis. In a primary myoblast cell-culture system, genetic and pharmacological approaches revealed that loss of cIAP1 dramatically increases the fusion of myoblasts into myotubes. NF-κB signalling occurs along a classical and an alternative pathway, both of which are highly active in cIAP1-/- myoblasts. Suppression of the alternative pathway attenuates myotube fusion in wildtype and cIAP1-/- myoblasts. Conversely, constitutive activation of the alternative pathway increases myoblast fusion in wildtype myoblasts. cIAP1-/- mice have greater muscle weight and size than wildtypes, as well as an increased number of muscle stem cells. These results identify cIAP1 as a regulator of myogenesis through its modulation of classical and alternative NF-κB signalling pathways. Loss of the structural protein dystrophin in the mdx mouse model of Duchenne muscular dystrophy leads to chronic degeneration of skeletal muscle. The muscle pathology is strongly influenced by NF-κB signaling. Given the roles demonstrated for cIAP1 in cell culture and in vivo, I asked whether loss of cIAP1 would influence muscle pathology in the mdx mouse. To address this question, double-mutant mice were bred lacking both cIAP1 and dystrophin (cIAP1-/-;mdx). Histological analyses revealed that double-mutant mice exhibited reduced indications of damage on several measures, as compared to single-mutant (cIAP1+/+;mdx) controls. Unexpectedly, these reductions were seen in the “slow-twitch” soleus muscle but not in the “fast-twitch” extensor digitorum longus (EDL) muscle. The improvements in pathology of double-mutant solei were associated with reductions in muscle infiltration by CD68-expressing macrophages. Finally, the double-mutant mice exhibited improved endurance and resistance to damage during treadmill-running exercise. Taken together, these results suggest that loss of cIAP1, through its multiple regulatory functions, acts to improve myogenesis and increase muscle resistance to damage.

skeletal muscle

myogenesis

Transcription factor

Apoptosis

Inhibitor of apoptosis

myoblast