Induction of HPV-16 Late Gene Expression Through Use of Small Molecule Drugs

Andrén, Caroline

January 2016

Cervical cancer is the second most common cancer in women worldwide. The principal cause of cervical cancer is infection with human papillomavirus (HPV). HPV-16 is a high-risk virus and it is responsible for a high portion of all HPV-caused cancers. The HPV-16 genome consists of early and late genes. The virus initially infects basal cells of the cervix epithelium and in these cells early genes are expressed, whilst late genes, L1 and L2, are only expressed in the upper cell layers of the epithelium. Proteins encoded by the late genes are highly immunogenic, thus it is speculated that expression of the late genes earlier in the virus life cycle could lead to clearance of the virus due to interference of the immune system.     The aim of this study was to treat reporter cell lines with three different small molecule drugs to see if they had the ability to induce HPV-16 late gene expression. The reporter cell lines used in this study had been previously created by transfecting HeLa-cells with plasmids representing the HPV-16 genome. In these plasmids, L1 is replaced with a CAT reporter gene that encodes the CAT protein, which can be easily quantified using a sandwich ELISA.     Upon treating the reporter cell lines with TPA, a significant induction of late gene expression was detected. Furthermore, treatment with valproic acid showed some induction of late gene expression. In conclusion, TPA and valproic acid was deemed to have potential to act as a candidate drugs for treatment of HPV infections.

Cell and Molecular Biology

Cell- och molekylärbiologi

In situ molecular profilling of the microenvironment of breast carcinoma

Kaira, Mustapha

January 2015

High stromal PDGF receptor B expression was shown to have strong prognostic value in a studyinvolving over 600 breast cancer patients however, the molecular role of the receptor in tumordevelopment remains unclear. In this project we studied the spatial distribution and expressionlevels of a panel genes and markers associated with PDGF signaling, in breast cancer tumormicroenvironment (TME) using a newly developed technique -in situ sequencing. The techniquerelies on padlock probes which we validated with corresponding RNA sequencing, microarray,and immunohistochemistry data. Our results showed that high PDGF receptor B mRNA colocalizedwith markers of two pathways, TGFβ and Hedgehog signaling; this suggests that theymight contribute to the PDGF-receptor B-driven tumor growth. We also showed that stromalPDGF signaling is stimulated predominantly by tumor cells. Finally, further expression profilingof each individual gene revealed that CXCL14 was mainly expressed in the stroma, ACTA2expression was enriched in the tumor/stroma boundary while the stem-cell marker, OCT3, wasexpressed in the interior of the tumor cells.

Sequencing

gene expression analysis

cancer genetics

RCA

padlock probe

Cell and Molecular Biology

Cell- och molekylärbiologi

Studies on various culture systems for chondrocytes and osteoblasts

Prittinen, Juha

January 2017

Osteoarthritis and osteochondral defects are ailments that are increasing in frequency as the lifespan of the population increases and sedentary lifestyle becomes more common. Osteoarthritis is an inflammatory disease that causes the progressive degeneration of articular surfaces and the underlying bone. Accidents and injuries can cause osteochondral defects similar to osteoarthritis. In both cases the structure of the articular cartilage fails, leading to pain and disability. Articular cartilage has a naturally poor ability to regenerate since there is no vasculature and it is aneural. The sparse chondrocytes mainly act to maintain the healthy extracellular matrix. Once the defect is severe enough, a surgical intervention becomes necessary. For small defects and young patients, a cell-based treatment can be used, whereas for larger defects and severe osteoarthritis a partial or whole joint arthroplasty is performed. Methods to repair osteochondral defects have been improving over the years as the inter-disciplinary understanding of joints, and what is required to repair them, has increased. However, there are still issues to solve in order to achieve consistently good results in both joint replacement and repair of cartilage. The main issue faced with current techniques used for joint replacement is poor integration of the artificial joint, leading to loosening at the bone interface over time, while cartilage repair techniques face the problem of generating mechanically inferior fibrocartilage. It is known that surface chemistry and structures at micro- and nanoscale influence cell behaviour, which can be utilised to guide their attachment, proliferation and phenotype. Scaffold-free approaches and mechanical stimulation have previously given promising results in generating articular neocartilage. This thesis aims at exploring tools and solutions to the problems involved in implant integration, chondrocyte expansion and neocartilage tissue engineering. We hypothesised that 1) ultra-short pulsed laser deposition can be used to create biocompatible coatings; 2) micropillars with nanoscale features can improve the maintenance of the chondrocyte phenotype in culture and 3) hypergravity can aid in the production of more native-like neocartilage constructs. Our studies showed that ultra-short pulsed laser ablation can be used to create various surfaces for studying cell behaviour. Cell viability was slightly higher on a rough titanium oxide, whereas the cell area was significantly smaller on rough titanium oxide, indicating a lower amount of focal adhesions. Nanopatterned microstructures were not capable of maintaining the chondrocyte phenotype in culture, but they were not disadvantageous either. Hypergravity might help in creating a native-like distribution of collagen and proteoglycans. The constructs were more uniform in shape, but biomechanically the constructs were not different from non-centrifuged controls.

Cell biology

chondrocyte

osteoarthritis

surface materials

topography

tissue engineering

mechanical stimulation

Cell and Molecular Biology

Cell- och molekylärbiologi

Activity-regulated retinoic acid signaling in olfactory sensory neurons

Login, Hande

January 2014

The aim of the studies included in the thesis is to better understand the interplay between neuronal activity-dependent gene regulation and the bioactive vitamin A metabolite all-trans-retinoic acid (RA) during postnatal development, refinement and maintenance of precise neuronal connectivity using the olfactory sensory neuron (OSN) in the olfactory epithelium (OE) of genetically modified mice as a model. We show that: Inhibition of RA receptor (RAR)-mediated transcription in OSNs reduces expression of the olfactory cyclic nucleotide-gated (CNG) ion channel, which is required for odorant receptor (OR)-mediated stimulus transduction. This, results in increased OSN death and errors in precise connectivity. The increased cell death may be a consequence of reduced intrinsic excitability and/or reduced influx of Ca2+ ions while the errors in connectivity may be due to altered OR-dependent expression of axonal guidance proteins, such as Kirrel-2 and Neuropilin-1. Expression of the RA catabolic enzyme Cyp26B1 in OSNs is positively regulated by RAR-mediated transcription as well as sensory stimulation in a CNG channel-dependent manner. This shows that neuronal activity and local vitamin A metabolism are parts of novel regulatory feedback loop controlling precise connectivity and neuronal survival. The feedback loop may be a form of homeostatic plasticity in response to global changes in neuronal activity. BACE1, an enzyme is implicated in Alzheimer´s disease, and Cyp26B1 are inversely regulated by CNG channel-dependent sensory stimulation. Cyp26B1 expression is switched on at birth, forms a topographic expression gradient in OE and inhibits BACE1 expression into an inverse counter gradient. Taken together these results reveal a novel neuronal activity-dependent mechanism by which sensory stimuli can shape spatial gene expression via altered RA bioavailability. Increased Cyp26B1 expression stimulates turnover of OSNs during adult neurogenesis by a non-cell-autonomous mechanism. The gradient of Cyp26B1 expression correlates with spatially-regulated diversification of OSNs into subpopulations that express different subsets of OR genes. Cyp26B1 expression influences spatial OR diversification of OSNs by two different mechanisms. In the ventrolateral OE, Cyp26B1 inhibits OR expression by blocking OSN differentiation at a stage that may be associated with the cell intrinsic mechanism regulating OR gene choice. In the dorsomedial OE the expression frequency of some ORs is unaltered while other increases, presumably as a consequence of neuronal activity-dependent competition. A probable function of graded and activity-dependent Cyp26B1 expression is to form a topographic partitioning of the olfactory sensory map into functional domains, which gradually differ from each other with regard to experience-driven plasticity and neurogenic potential along the dorsomedial-ventrolateral axis of OE.

mouse olfactory system

RA

neuronal activity

CNG

Cyp26B1

BACE1

Kirrel-2

Cell and Molecular Biology

Cell- och molekylärbiologi

Advanced Detection Methods of Genomic Barcodes for Genotyping Escherichia coli Libraries

Eger, Nicole

January 2021

Pooled cell strain libraries are a powerful tool allowing to investigate the influence of genetic modifications on phenotypes in high throughput single-cell assays. To link the genotype to phenotype in each cell of the library, unique 20 base pairs (bp) long barcodes are used to allow in situ genotyping after phenotyping via fluorescence microscopy. In previous studies, these barcode sequences were expressed from high copy number plasmids resulting in a high number of targets for detection via fluorescence in situ hybridization (FISH) and thus, a strong readout signal. However, constant selection pressure must be applied on the cells to maintain the foreign plasmid DNA which may influence the phenotype. Inserting unique barcodes on the chromosome ensures stability of the construct which is required for some genomic library applications. However, the low copy number of the barcode sequence often requires an additional step of DNA amplification for efficient detection. In this study, two methods for barcode amplification were investigated. First, amplification from the double stranded DNA upon binding of peptide nucleic acids and subsequent amplification via rolling circle amplification (AmPPR). Second, amplification from genomic DNA or cDNA via loop-mediated isothermal amplification (LAMP). Whereas the AmPPR approach remained unsuccessful, chromosomal barcode sequences were successfully amplified in situ via LAMP and subsequently detected using FISH. I show that LAMP can potentially be a quick, specific, and elegant amplification technique for in situ genotyping in microfluidic devices. However, nonspecific amplification and partly nonspecific readout signals when using LAMP remain a problem and need to be further investigated before implementing this method on pooled libraries.

Genotyping

Genomic barcodes

LAMP

PNA

RCA

FISH

Cell and Molecular Biology

Cell- och molekylärbiologi

GENETIC ANALYSIS OF PUTATIVE WALLEYE AND SAUGEYE IN RIVERS NEAR FORT WAYNE, INDIANA

Gabriel L Curtis (9182993)

03 August 2020

<p>A saugeye is the progeny of a female walleye (<i>Sander vitreus)</i> and male sauger (<i>Sander canadensis)</i>. In the United States, hybrid saugeyes are considered important for recreational fisheries and as a potential food source. Saugeyes grow exceptionally faster than their non-hybrid parents and are more tolerant of a broader range of water conditions. They are also of interest to anglers due to their increased growth rate and ease to catch. Rather unexpectedly, biologists have recently observed fish that they believe to be saugeye in the Fort Wayne Rivers even though only walleye have been stocked in the area. The fish in Hurshtown Reservoir are believed to be walleye and the identification of those in the Three Rivers is unknown. A potential source for saugeye in the Fort Wayne Rivers is St. Marys State Fish Hatchery in Ohio. This research aims to determine if the fish found in the Fort Wayne Rivers are walleye or saugeye using microsatellite analysis. Microsatellites at seven loci were genotyped for 20 reference walleye, sauger, and saugeye as well as 21 unknown fish caught near Fort Wayne. Of the fish caught near Fort Wayne, three are from Hurshtown Reservoir and 18 are from the Three Rivers. Assignment tests of genotypes were completed using model and non-model based cluster analysis. Genotypic variation clearly resolved the two parent species from their hybrid offspring. Sixteen of eighteen <i>Sander</i> (unknown species) caught in Fort Wayne Rivers between 2018 and 2019 were determined to be first generation saugeye. The other two were walleye found in the Maumee River downstream of Hosey Dam. The three <i>Sander</i> caught in Hurshtown Reservoir were verified to be walleye. Sauger have never been stocked in the Fort Wayne Rivers and connecting waterways. Therefore, it is not likely that the saugeye found in the analysis are from natural reproduction. It is speculated that saugeye are swimming to Fort Wayne from hatcheries within the Maumee watershed. There are many potential sources for walleye in the Fort Wayne Rivers. </p>

Genetics

Animal Cell and Molecular Biology

Vertebrate Biology

Walleye

Saugeye

Microsatellites

Maumee River watershed

Fort Wayne

Functional and Structural Characterization of TET/JANUS Signaling Complexes in A. Thaliana Sperm Cells

Ryan L Hockemeyer (9193580)

03 August 2020

<p>Plants are used as a primary food source by humans. Some plants produce edible roots or leaves, but most crops used today are grown to harvest their nutrient-rich seeds which are a product of double fertilization in flowering plants. </p> <p>Cell-cell recognition, adhesion, and fusion are widespread phenomena in many biological processes, where fertilization is an exemplary process. Many players have been identified to mediate sperm-egg fusion in both animals and plants. Interestingly several of these components were shown to be structurally and functionally conserved across kingdoms. In animals Tetraspanins act as facilitators of sperm-egg fusion. Tetraspanins are known to associate in clusters in the plasma membrane of cells, where they recruit diverse signaling proteins, forming the so called Tetraspanin-enriched microdomains (TEMs). TEMs are therefore recognized as major signaling platforms mediating specific cellular processes in the plasma membrane of cells. Two <i>Arabidopsis</i>-expressed tetraspanins, <i>TET11</i> and <i>TET12</i>, are highly expressed in the sperm cells (SCs), however their function in fertilization are unknown. Using fluorescence microscopy, we quantified the expression of TETs in SCs and found evidence for the existence of a Tetraspanin-enriched microdomain (TEM) at the SC-SC adhesion interface. Sperm cell factors which are necessary for fertilization were found to accumulate at the TEM, suggesting that plant SC TEMs may function as protective platforms for fertilization factors. Sperm-expressed TETs directly interact with members of a novel, plant-specific family of unknown proteins, <i>DMP8/9</i>. DMP8/9 function as negative regulators of SC-SC adhesion and are required for double fertilization. Structural and functional analysis suggest that these two proteins may perform unique functions as membrane remodelers in SCs. In addition, we provide evidence of a new GEX2 function as a SC-SC adhesion factor and potential partner of TET-DMP complexes at the SC-SC interface.</p>

Plant Biology

Plant Cell and Molecular Biology

Double Fertilization

Cell Adhesion

Tetraspanin

Derivation and characterization of pacemaker cells from human induced pluripotent stem cells for investigation of cardiotoxicity

Markó, Dorottya

January 2021

No description available.

stem cell

cardiomyocyte

differentiation

Cell Biology

Cellbiologi

Cell and Molecular Biology

Cell- och molekylärbiologi

Compounds screening for the identification of novel drug to improve the Knock in efficiency mediated by CRISPR-Cas9

Anagnostou, Evangelia

January 2023

Genome editing is an exciting field that allows for the precise modification of an organism's DNA. One of the most advanced tools in this area is CRISPR/Cas9 (Clustered Regularly Interspaced Short Palindromic Repeats/CRISPR-associated protein 9), which creates a DSB (Double-strand break) at a specific location in the genome. This break can then be repaired by the cell using one of two pathways – NHEJ (nonhomologous end joining) or HDR (homology-directed repair) HDR leads to more precise repair and is used to create KI (Knock-In) modifications by introducing a homologous piece of DNA with the desired changes. However, HDR is a rare event that competes with the error prone NHEJ pathway, limiting its efficiency. HDR mainly occurs in the G2 and S phases of the cell cycle, making it a challenge to control and target. To improve KI efficiency, researchers have used strategies such as inhibiting NHEJ or activating HDR. This study focuses on identifying direct and indirect activators of HDR through a library assay screening. We established a robust method for screening compounds in HEK293 cells that relies on a plasmid-based delivery Cas9, gRNA (guide RNA), and synthetic ssDNA (single strand DNA). Out of 3,000 compounds screened, 1% showed a higher signal than the positive control, and approximately 10% presented a higher signal than untreated cells. The top 5 compounds were further validated in dose response. Our system opens new avenues for improving the efficiency of KI modifications.

Genome editing

Knock in

HDR

CRISPR-Cas9

screening

NHEJ

Cell and Molecular Biology

Cell- och molekylärbiologi

Notch signalling in carcinogenesis : With special emphasis on T-cell lymphoma and colorectal cancer

Ungerbäck, Jonas

January 2009

The Notch signalling pathway is an evolutionary conserved pathway, named after the Notch receptors, Notch1-4 in mammals, which upon cell-cell contact and ligand binding releases the intracellular domain (NICD). NICD translocates into the nucleus where it binds the transcriptional repressor RBP-Jk, which together with co-activators belonging to the Mastermind-like family of proteins form a transcriptional activation complex. This complex activates genes controlling cell fate decision, embryonic development, proliferation, differentiation, adult homeostasis and stem cell maintenance. On the other hand, disrupted Notch signalling may result in pathological conditions like cancer, although the mechanisms behind the disruption are often complex and in many cases largely unknown. Notch1 drives the lymphocyte differentiation towards a T-cell fate and activating mutations in the gene have been suggested to be involved in T-cell lymphoma. In paper I, genetic alterations in Notch1 and the Notch1 regulating gene CDC4 were investigated in tumours from murine T-cell lymphoma induced with phenolphthalein, 1,3-butadiene or 2’,3’-dideoxycytidine. We identified activating Notch1 mutations in 39% of the lymphomas, suggesting that Notch1 is an important target gene for mutations in chemically induced lymphomas. While it is known that constitutively activated Notch signalling has a clear oncogenic function in several solid malignancies as well, the molecular mechanisms are less known in this context. Unpublished data of our lab, together with other recent studies, suggest that mutations of Notch and Notch-related genes per se are uncommon in solid malignancies including colorectal cancer, while a growing body of evidence indicates that aberrant Wnt/b-catenin signalling may result in pro-tumoural Notch activation in these contexts. In paper II, we therefore investigated potential transcriptional interactions between the Notch and Wnt signalling pathways in colorectal cancer cell lines. The proximal Notch and Wnt pathway gene promoters were bioinformatically identified and screened for putative TCF/LEF1 and RBP-Jk sites. In canonical Wnt signalling, Apc negatively regulates b-catenin leading to repression of TCF/LEF1 target genes. Upon repression of the Wnt pathway we observed that several genes in the Notch pathway, including Notch2, were transcriptionally downregulated. We also confirmed binding of Lef1 to Notch2 as well as other Notch pathway gene promoters and luciferase assays showed an increased activity for at least one LEF1/TCF-site in the Notch2 promoter upon co-transfection of HT29 or HCT116 cells with mutated b-catenin. HT29 cell lines were also treated with the g-secretase inhibitor DAPT, leading to inactivation of the Notch pathway by preventing release of NICD. However, results showed no effects on Apc, b-catenin or their target cyclin D1. Taken together, these results indicate that the Wnt pathway may function as a regulator of the Notch pathway through the TCF/LEF1 target gene program in colon cancer cell lines. In summary, Notch pathway deregulation is of importance in both murine T-cell lymphoma and human colorectal cancer, although the mechanisms differ. The current results give new insights in Notch pathway alterations as well as the signalling networks in which the Notch pathway interacts, and thus increase the understanding of Notch’s involvement in malignant diseases. / Studies on molecular genetic alterations in colorectal cancer

Notch signalling

T-cell lymphoma

colorectal cancer

Wnt signalling

transcription

Cell and Molecular Biology

Cell- och molekylärbiologi