Cellular design of heparan sulfate : The NDST enzymes and their regulation

Carlsson, Pernilla

January 2008

Heparan sulfate proteoglycans are proteins with long, unbranched heparan sulfate (HS) polysaccharide chains attached to them. They are found on cell surfaces and in basement membranes where they exert their action by interacting with a wide range of enzymes and signaling molecules and are thereby involved in a range of various processes both during embryonic development and in adult physiology. A great part of the biological functionality of proteoglycans can be directly related to the polysaccharide part. HS chains display very variable sulfation patterns where highly sulfated regions are responsible for a large part of the biological activity. The biosynthesis of HS is a complex process in which a number of enzymes are involved. Better comprehension of how this process is regulated could reveal clues to how formation of HS sulfation patterns occurs, and thereby how HS functionality is controlled. This thesis is focusing on regulation of one of the enzymes responsible for HS sulfation, glucosaminyl N-deacetylase/N-sulfotransferase (NDST), in an attempt to understand these mechanisms better. Different aspects of NDST regulation were studied in three projects: I) “Heparin/heparan sulfate biosynthesis: Processive formation of N-sulfated domains”, where the sulfate donor PAPS is shown to influence the manner in which NDST modifies the substrate, affecting the domain structure of the polysaccharide. II) “Heparan sulfate biosynthesis: Characterization of an NDST1 splice variant”, where a splice variant of NDST1 which appears to influence NDST1 protein levels and affect HS structure is described. III) “Heparan sulfate biosynthesis in zebrafish: Five NDST genes with distinct expression patterns during embryonic development”, in which five zebrafish NDSTs were cloned and shown to be expressed in a temporally and spatially regulated manner.

heparan sulfate

heparin

proteoglycan

NDST

PAPS

Golgi

Cell and molecular biology

Cell- och molekylärbiologi

Stereotyped B Cell Receptors in Chronic Lymphocytic Leukaemia : Implications for Antigen Selection in Leukemogenesis

Murray, Fiona

January 2008

Biased immunoglobulin heavy variable (IGHV) gene usage and distinctive B-cell receptor (BCR) features have been reported in chronic lymphocytic leukaemia (CLL), which may reflect clonal selection by antigens during disease development. Furthermore, the IGHV gene mutation status distinguishes two clinical entities of CLL, where patients with unmutated IGHV genes have an inferior prognosis compared to those with mutated IGHV genes. Recently, one subgroup of CLL patients expressing the IGHV3-21 gene was found to display highly similar immunoglobulin (IG) gene features, even within the heavy chain complementarity-determining region 3 (HCDR3). Patients in this subgroup typically had a poor prognosis. In paper I, we aimed to identify further subgroups with restricted BCR features among 346 CLL cases. Six subsets were defined which carried virtually identical BCRs in terms of rearranged heavy and light chain (LC) IG genes and CDR3 length and composition. In paper II, we investigated 90 IGHV3-21 cases from diverse geographical locations. We confirmed the highly restricted HCDR3 characteristics in 56% of patients and a biased usage of the IGLV3-21 gene in 72% of cases. Survival analysis also confirmed the poor outcome of this group, irrespective of IGHV gene mutation status and geographical origin. Papers III and IV involved a large-scale analysis of IGH and IG kappa and lambda (IGK/L) gene rearrangements, to define subsets with ‘stereotyped’ BCRs and also to systematically examine the somatic hypermutation (SHM) features of the IG genes in CLL. We studied a cohort of 1967 IGH and 891 IGK/L gene sequences from 1939 patients from 6 European institutions. Over 5300 IGH and ~4700 IGK/L sequences from non-CLL B cells were used as a control data set. In total, 110 CLL stereotyped subsets were defined according to HCDR3 homology. Striking IGK/L gene biases were also evident within subsets, along with distinctive K/LCDR3 features, such as length and amino acid composition. At cohort level, the patterns of mutation appeared to be consistent with that of a canonical SHM mechanism. However, at a subgroup level, certain stereotyped subsets, e.g. IGHV3-21/IGLV3-21 and IGHV4-34/IGKV2-30 CLL, deviated from this pattern. Furthermore, recurrent ‘stereotyped’ mutations occurred in cases belonging to subsets with restricted HCDR3s, in both IGHV and IGK/LV genes, which were subset- and CLL-biased when compared to non-CLL B cells. In conclusion, our findings implicate antigen selection as a significant factor in the pathogenesis of CLL, particularly in cases carrying stereotyped BCRs. The presence of stereotyped mutations throughout the VH and VL domain also indicates involvement of IG regions other than the CDR3 in antigen recognition. Finally, biased IGK/L gene usage and specific K/LCDR3 features are strong indications that LCs are crucial in shaping the specificity of leukemic BCRs, in association with defined heavy chains.

chronic lymphocytic leukaemia

immunoglobulin genes

somatic hypermutation

stereotyped B cell receptors

antigen selection

Molecular biology

Molekylärbiologi

Localization of AtHOG1 and AtHOG2 in Arabidopsis plants at the tissue and subcellular levels

Guszpit, Emilia

January 2010

Plant hormones are responsible for plant growth and adaptation to the environment. Among them the most important are cytokinins. Plants undergo gene silencing processes called homology-dependent gene silencing processes. In Arabidopsis there are two homology-dependent gene silencing genes that were chosen for further study, namely AtHOG1 and AtHOG2. Transgenic plants were generated previously with ten different constructs containing AtHOG1 or AtHOG2 genes and were used in this study. Some of the constructs had GFP attached so that the protein expressed could be visualised in a confocal microscope. Transgenic plants generated were T1 and T2 generations. Their DNA was extracted from leaves. By means of PCR transgenic plants were identified. There were 147 samples. Among them there were 39 positiveswith BAR primers and 32 positives with construct specific primers. The localisation of the HOG2 protein was observed in a confocal microscope. Seeds used were T3 generation and were obtained from the lab. HOG2 protein was found to be localised in cell membrane, root tip and chloroplasts.

transgenic Arabidopsis

transgenic plants

HOG1 gene

Cell and molecular biology

Cell- och molekylärbiologi

Tracking an elusive predator: Studying the Scandinavian lynx population by use of genetic markers

Berlin, Ingrid

January 2007

Abstract Gaining accurate population information is crucial for the conservation and management of species. The National Monitoring Program for Large Carnivores monitors the Swedish lynx population (species Lynx lynx) by surveying family groups, non-invasive sampling and genetic analysis. Ten microsatellite regions were used as genetic markers to retrieve unique individual genotypes, through polymerase chain reactions (PCR) with specific primer-pairs and capillary-electrophoresis. Complete genotypes were matched using an internal database. The aim of this degree project was to show how monitoring of lynx through genetic analysis is carried out at the Department of Evolutionary Biology at Uppsala University, and to evaluate how effective these methods are and how they might be improved. Even though most of the methods used were fairly robust and reproducible, non-invasive sampling and microsatellite analysis posed some problems regarding DNA quality and quantity, and increased the risks of certain genotyping errors. These risks might be worth taking though, as genetic analysis, in combination with field observations, gives a more comprehensive picture of the Swedish lynx population.

Lynx

Genetic marker

Microsatellite

Non-invasive sampling

Faecal DNA

Molecular biology

Molekylärbiologi

No indications of socially induced changes in brain aromatase activity in guppy (Poecilia reticulata) males

Rohyo, Izla

January 2008

Aromatase is the enzyme that catalysis the conversion of androgens into estrogens. It´s a member of P450 cytochrome family and is encoded by the CYP19-gene. The enzyme aromatase has an important role in regulating physiological and behavioral sexual mechanisms. This includes for instance activation, motivation and maintenance of the reproductive behaviors. The sexual behavior is affected by a complex series of events that requires the connection of endogenous hormonal and neurochemical changes with social interactions, especially between the opposite sexes. The aim of the present study was to examine how social interactions effect the aromatase expression and activity in the guppy brain. Guppy males were introduced into four different social conditions: Isolated, all male conditions, heterospecific (with zebrafish females) and conspecific female guppies. The focal males were kept under these conditions for two respectively four days. The sexual behavior, of each of the focal males was recorded daily during 10 minutes. The males with the guppy females showed, in contrast to the males in the other groups, a high frequency of reproductive behaviors. The brains of the focal males were collected and the brain aromatase activity was measured using tritiated water assay. I have also tried to analyze the gene-expression of aromatase with RT-PCR. However I was unable to analyze the results with the RT-PCR, because of possible primer-dimerization. Due to the limited time schedule, we were not able to solve the problem. ANOVA performed on the aromatase activity, revealed no significant difference between the different treatment groups. The variance was highest in the zebrafish category and lowest in the isolated males. There was no significant correlation between the mean number of reproductive behaviors and the aromatase activity in males that were together with guppy females. The results do not support the hypothesis that social interactions can affect the brain aromatase activity in guppy males.

Aromatase

guppy

social interactions

Real-time PCR

aromatase activity

Molecular biology

Molekylärbiologi

Characterization of two Protein Disulfide Oxidoreductases from Thermophilic Organisms Pyrococcus furiosus and Aquifex aeolicus : Characterization of two Protein Disulfide Oxidoreductases

Fürtenbach, Karin

January 2008

Members of the thioredoxin superfamily of proteins catalyze disulfide bond reduction and oxidation using the active site C-X-X-C sequence. In hyperthermophilic organisms, cysteine side chains were expected in low abundance since they were not believed to endure the high temperatures under which they grow. Recently it has been found that disulfide bonds in hyperthermophiles are more frequent, the higher the growth temperature of the organism. This is perhaps used as an adaptation to high temperature in order to stabilize proteins under harsh conditions. A protein with sequence and structural similarities to mesophilic members of the thioredoxin superfamily, called protein disulfide oxidoreductases (PDO), has been found in the genomes of recently sequenced hyperthermophilic genomes. In this study PDOs from the hyperthermophiles Aquifex aeolicus (AaPDO) and Pyrococcus furiosus (PfPDO) have been investigated. The molecular weight is about 26 kDa and their structures are comprised of two homologous thioredoxin folds, referred to as the N-unit and the C-unit, each containing a C-X-X-C motif. The sequence identity between the two units and the two proteins is low, but they are still structurally very similar. The function of these proteins in vivo is unknown. As a first step in characterizing the activity of these proteins, the redox characteristics of these domains will be investigated. During this project, the genes for AaPDO and PfPDO have been cloned into overexpression vectors, expressed in E. coli and purified to homogeneity. To allow for individual study of the activities of two units, mutated proteins were prepared in which the cysteine residues of the N-unit (AaPDOnm and PfPDOnm) and of the C-unit (AaPDOcm and PfPDOcm) and purified. Circular dichroism spectra recorded of the wild type and mutants indicate that all purified proteins are folded and that the N- and C-unit active site mutants are structurally similar to the corresponding wild type proteins.

PDO

protein disulfide oxidoreductase

Pyrococcus furiosus

Aquifex aeolicus

disulfide

Molecular biology

Molekylärbiologi

Protein tyrosine kinases and the regulation of signalling and adhesion in drosophila melanogaster

Grabbe, Caroline

January 2007

In order to build a multi-cellular organism and to regulate cellular functions, cells need to communicate with each other, as well as tightly regulate their behaviour in response to environmental changes. For these purposes all eukaryotic cells express a large number of membrane spanning receptors that either themselves contain catalytic activity or via cytoplasmic effector enzymes, function to transmit “signals” from the cell exterior to induce appropriate responses within the cell. Protein tyrosine kinases (PTKs) are important signalling molecules, represented by the transmembrane receptor tyrosine kinases (RTKs) in addition to the cytoplasmic non-receptor PTKs, which alter cell behaviour by phosphorylating target proteins. An additional requirement for proper signalling and multicellular organisation is the adhesion between cells as well as adhesion of cells to the extracellular matrix (ECM). Adhesion between cells and the ECM is mainly mediated by the integrin family of cell surface receptors, which functions as a structural link between the ECM and the actin cytoskeleton as well as important centres for signalling. Mammalian studies have implicated the cytoplasmic Focal Adhesion Kinase (FAK), as a major transmitter of signalling emanating from integrins, regulating cell migration, survival, proliferation and differentiation. In our studies of the sole FAK family member in Drosophila, Fak56, we have concluded that the deletion of Fak56 from the fruit fly genome causes no obvious defects in integrin-mediated adhesion, migration or signalling in vivo. Consequently, in contrast to the embryonic lethality observed in mouse knockouts, Fak56 mutant flies are both viable and fertile. However, we do find a clear genetic interaction between Fak56 and Drosophila integrins. Additionally, overexpression studies indeed indicate Fak56 as a negative regulator of integrin adhesion, given that excess Fak56 protein phenocopies loss of integrin function, causing phenotypes such as muscle detachment and wing blistering. In Drosophila, as well as in mammals, FAK family proteins are highly abundant in the CNS and in our studies we have identified a requirement of Fak56 in synaptic transmission at neuromuscular junctions. Lack of Fak56 causes a weakening of action potential conduction, resulting in sensitivity to high-frequency mechanical and electrical stimulation, manifested by epileptic-like seizures and paralysis in Fak56 mutants, a phenotype known as Bang Sensitivity (BS) in flies. We also show that Fak56 phosphorylation is directly modulated in response to alterations in intracellular calcium levels, supporting a role for Fak56 in neurotransmission. Fak56 is directly activated by the Drosophila Anaplastic Lymphoma Kinase, DAlk, receptor which was identified in our lab. We characterised DAlk as a novel RTK that is expressed in the embryonic CNS and mesoderm where it drives activation of the ERK/MAPK pathway. Indeed, we found DAlk to ectopically induce protein tyrosine phosphorylation and specifically phosphorylation of ERK, resulting in autonomous cell transformation and uncontrolled tissue growth. Subsequently, we identified a requirement for DAlk function during Drosophila embryogenesis, where it displays an essential role in gut development. Specifically, we identified the secreted molecule Jelly belly (Jeb) as a ligand for DAlk and showed that Jeb-DAlk interaction activates an ERK-mediated signalling pathway essential for visceral muscle specification and fusion, and consequently formation of the gut. The potent ability of PTKs to regulate cell behaviour, together with the strong linkage between RTK dysregulation and tumour formation, renders the negative regulation of kinase activity an important area of research. We have identified the Drosophila homologue of Cbl-interacting protein of 85kDa, dCIN85, an adaptor molecule which in mammalian cells has shown involvement in RTK endocytosis and downregulation, as well as in the regulation of actin cytoskeleton dynamics. In the fruit fly, dCIN85 displays essential functions, given that dCIN85 loss of function mutants display a grand-child less phenotype. Generation of a dCIN85 antibody, together with isoform-specific transgenic flies, have allowed us to observe a punctuate localization pattern of the SH3-domain containing dCIN85 variants, representing Rab5-positive endosomal structures. This, in addition to the confirmation of a direct dCIN85-dCbl interaction, indicates an evolutionary conservation of dCIN85 function. Interestingly, dCIN85 co-localises with dRICH1, a Cdc42 specific RhoGAP, in differentiated photoreceptor cells in eye imaginal discs. This may imply a role for dCIN85 in the regulation of the specialised endocytic recycling processes required for the assembly/maintenance of tight junctions and establishment of cell polarity in epithelial tissues.

Drosophila

Signalling

Adhesion

Protein Tyrosine Kinase

Development

Endocytosis

Molecular biology

Molekylärbiologi

Expanding role of caveolae in control of adipocyte metabolism : proteomics of caveolae

Aboulaich, Nabila

January 2006

The primary function of adipose tissue is to store energy in the form of triacylglycerol, which is hydrolyzed to fatty acids to supply other tissues with energy. While insulin promotes the storage of triacylglycerol, catecholamines stimulate its hydrolysis. The development of type II diabetes is strongly associated with obesity, indicating a role of triacylglycerol metabolism in the pathogenesis of diabetes. Caveolae are plasma membrane invaginations found in most cells but are highly abundant in adipocytes. Insulin receptors are localized in caveolae and their function depends on intact caveolae structures. In the present thesis work, mass spectrometry-based methodology allowed identification of a number of new proteins and their posttranslational modifications in caveolae of human adipocytes. Variable N-terminal acetylation and phosphorylation of caveolin-1α and caveolin-1β were identified, which might regulate the function of caveolae. The transcription regulator protein PTRF was identified as the major caveolae associated protein. Specific proteolytic modifications of PTRF at the cytosolic surface of caveolae and phosphorylation on nine serine and one threonine residues were identified. Moreover, insulin induced translocation of PTRF from the plasma membrane to the nucleus. PTRF was previously shown to regulate the activity of both RNA polymerase I and polymerase II, thus a role of PTRF in mediating the anabolic action of insulin on protein synthesis and gene transcription is proposed. PTRF was also involved in an extranuclear function in the hormonal regulation of triacylglycerol metabolism in caveolae. PTRF was colocalized with the triacylglycerol regulator proteins perilipin and hormone-sensitive lipase (HSL) in the triacylglycerol-synthesizing caveolae subclass. We showed that, while perilipin was translocated to the plasma membrane, both PTRF and HSL were translocated from the plasma membrane to the cytosol as a complex in response to insulin. The perilipin recruited to the plasma membrane was highly threonine phosphorylated. By mass spectrometry, three phosphorylated threonine residues were identified and were located in an acidic domain in the lipid droplet targeting domain of perilipin. The insulin-induced recruitment of perilipin to the plasma membrane might, therefore be phosphorylation-dependent. Isoproterenol, which stimulates hydrolysis of triacylglycerol, induced a complete depletion of perilipin B from the plasma membrane, suggesting a function of perilipin B to protect newly synthesized triacylglycerol in caveolae from being hydrolyzed by HSL. The location of PTRF and HSL was not affected by isoproterenol, indicating that insulin is acting against a default presence of PTRF and HSL in caveolae. Taken together, this thesis expands our knowledge about caveolae and provided valuable information about their involvement in novel roles, particularly in the hormonal regulation of triacylglycerol metabolism.

Diabetes

Insulin signalling

Fatty acid metabolism

Proteomics

Mass spectrometry

Cell and molecular biology

Cell- och molekylärbiologi

VanT, a central regulator of quorum sensing signalling in Vibrio anguillarum

Croxatto, Antony

January 2006

Many bacteria produce signal molecules that serve in a cell-to-cell communication system termed quorum sensing. This signalling system allows a bacterial population to co-ordinately regulate functions according to their cell number in a defined environment. As bacterial growth progresses towards the stationary phase, signalling molecules accumulate in the growth medium and, above a certain threshold level, regulate the expression of genes involved in diverse functions. Most of the functions monitored by quorum sensing are most beneficial when they are performed as a population than by single cells, such as virulence factor production, biofilm formation, conjugation and bioluminescence. Vibrio anguillarum is a bacterial pathogen that causes terminal hemorrhagic septicaemia in marine fish. V. anguillarum possesses multiple quorum sensing circuits similar to the LuxI/LuxR and the V. harveyi-type systems. In this study, a characterisation of the quorum sensing-regulated transcriptional activator VanT was made. VanT belongs to the V. harveyi LuxR family of transcriptional regulators, which play a central role in quorum sensing signalling in Vibrio species. VanT was shown to regulate serine, metalloprotease, pigment, exopolysaccharide (EPS) and biofilm production. VanT repressed an EPS locus that plays a critical role in bacterial colonization of the fish integument and virulence. The V. harveyi-like quorum sensing systems were shown to limit rather than induce vanT expression throughout growth in V. anguillarum. In contrast to homologous proteins in other Vibrio spp., the quorum sensing phosphorelay protein VanU and the response regulator VanO had antagonistic roles in the regulation of vanT expression. Unlike other members of the luxR family, vanT was expressed at low cell density and no significant induction due to quorum sensing regulation was seen. Interestingly, VanT expression was induced by the alternative sigma factor RpoS as the cells entered stationary phase. RpoS was shown to regulate VanT expression post-transcriptionally by promoting vanT mRNA stability. VanT and RpoS were important for bacterial survival under stress conditions, indicating that VanT is likely an essential factor of V. anguillarum stress response.

Vibriosis

Vibrio anguillarum

quorum sensing

two-component phosphorelay systems

Molecular biology

Molekylärbiologi

The control of growth and metabolism in Caenorhabditis elegans

Friberg, Josefin

January 2006

The control of growth is a poorly understood aspect of animal development. This thesis focuses on body size regulation in Caenorhabditis elegans, and in particular, how worms grow to a certain size. In C. elegans, a key regulator of size is the TGFβ homologue DBL-1. Mutations that deplete the worm of DBL-1 result in a small body size, whereas overexpression of the gene renders long animals. The small mutants have the same number of cells as wild type suggesting that some or all cells are smaller. DBL-1 activates a TGFβ receptor leading to the nuclear localization of three Smad proteins which then initiate a transcriptional program for size control whose targets are mainly unknown. In order to learn more about how body size in C. elegans is regulated, we set up EMS mutagenesis screens to identify new loci that caused a long phenotype. A subset of the genes we have identified might function in the TGFβ signaling pathway regulating growth while others likely function in parallel pathways. One gene that we found in this screen, lon-3, encodes a cuticle collagen that genetically lies downstream of the DBL-1 TGFβ signaling pathway. Interestingly, loss of function mutations in lon-3 result in a Lon phenotype, whereas increasing the amount of LON-3 protein cause the worms to be dumpy, i.e. shorter, but slightly fatter than wild type. LON-3 is expressed in the hypodermis, the tissue from which the cuticle is synthesized and in which TGFβ signaling, regulating body size, has its focus. This study and previous work have shown that DBL-1 may affect body volume via effects on hypodermal nuclear ploidy, however this is unaffected in lon-3 mutants. Consistent with this finding, the volume of lon-3 mutant worms is not different from wild type. Taken together, our results suggest that another mechanism, by which TGFβ signaling can regulate body length, is by altering the shape of the cuticle via its effect on lon-3 and possibly other cuticle collagens. Studies in worms, flies and mice show that body size and nutrient allocation are closely connected. p70 S6-kinase (S6K) is a known regulator of cell and body size that also plays a role in metabolism. In mice and flies S6K mutants are much smaller than wild type. Our work on the worm homolog, rsks-1, shows that in worms as well, this gene is important for growth regulation and cell size. However, this effect seems to be at least in part independent of DBL-1 TGFβ signaling. Furthermore, rsks-1mutants have a 50 % increase in the amount of stored fat. Fatty acid metabolism has been shown to play an important role in environmental adaptation, especially in regards to temperature changes. Consistent with this idea, rsks-1 mutants appear to have difficulties in adjusting to such changes, reflected in a much-decreased fecundity at 15 and 25 °C compared to their cultivation temperature (20 °C). Within the nervous system the gene is specifically expressed in a subset of the chemosensory neurons that, when nutrients are abundant, secrete signals that promote growth. Intriguingly, this expression seems to be negatively regulated by insulin- like signaling, in contrast to the positive regulation of S6K by insulin in Drosophila and mice. Taken together we show that rsks-1 is an important regulator of growth and fat metabolism in Caenorhabditis elegans.

TGFβ

insulin

collagen

p70 S6K

metabolism

growth

dauer

Caenorhabditis elegans

Cell and molecular biology

Cell- och molekylärbiologi