Anti-parasitic and anti-viral immune responses in insects

Terenius, Olle

January 2004

Insects encounter many microorganisms in nature and to survive they have developed counter measures against the invading pathogens. In Drosophila melanogaster research on insect immunity has mainly been focused on infections by bacteria and fungi. We have explored the immune response against natural infections of the parasite Octosporea muscaedomesticae and the Drosophila C virus as compared to natural infections of bacteria and fungi. By using Affymetrix Drosophila GeneChips, we were able to obtain 48 genes uniquely induced after parasitic infection. It was also clearly shown that natural infections led to different results than when injecting the pathogens. In order to search for the ultimate role of the lepidopteran protein hemolin, we used RNA interference (RNAi). We could show that injection of double stranded RNA (dsRNA) of Hemolin in pupae of Hyalophora cecropia led to embryonic malformation and lethality and that there was a sex specific difference. We continued the RNAi investigation of hemolin in another lepidopteran species, Antheraea pernyi, and discovered that hemolin was induced by dsRNA per se. A similar induction of hemolin was seen after infection with baculovirus and we therefore performed in vivo experiments on baculovirus infected pupae. We could show that a low dose of dsHemolin prolonged the period before the A. pernyi pupae showed any symptoms of infection, while a high dose led to a more rapid onset of symptoms. By performing in silico analysis of the hemolin sequence from A. pernyi in comparison with other Hemolin sequences, it was possible to select a number of sites that either by being strongly conserved or variable could be important targets for future studies of hemolin function.

Hemolin

Hyalophora cecropia

Antheraea pernyi

Drosophila melanogaster

anti-viral

anti-parasitic

rna interference

microarray

innate immunity

Genetics

Genetik

Risk Prediction at the Emergency Department

Olsson, Thomas

January 2004

The severity of illness was scored in a cohort of 11751 non-surgical patients presenting at the Emergency Department (ED) during 12 consecutive months and followed for 4.7 years. The scoring system Rapid Acute Physiology score (RAPS) (including blood pressure, respiratory rate, pulse rate and Glasgow coma scale) was calculated for all arrivals at the ED. The RAPS system was also additionally developed by including the peripheral oxygen saturation and patient age, resulting in the new Rapid Emergency Medicine Score, (REMS). REMS was superior to RAPS in predicting in-hospital mortality according to ROC-curve analysis. An increase of one point in the 26 point REMS scale was associated with an Odds ratio of 1.40 for in-hospital death (95% CI 1.36-1.45, p<0.0001). Similar results were obtained in the major patient groups (chest pain, stroke, coma, dyspnea and diabetes). The association between REMS and length of stay in hospital was modest. Charlson Co-morbidity Index could add prognostic information to REMS in a long-term (4.7 years), but not in a short-term perspective (3 and 7 days). REMS was shown to be as powerful a predictor of in-hospital mortality as the more complicated APACHE II. REMS at the ED could also predict long-term mortality (4.7 years) in the total cohort (Hazard ratio 1.26, p<0.0001). REMS is a potentially useful prognostic tool for non-surgical patients at the ED, regarding both in-hospital and long-term mortality. It is less complicated to use than APACHE II and has equal predictive accuracy.

Medicine

scoring system

mortality

cohort

prospective

Emergency Department

Medicin

Comparative Genomics in Birds

Axelsson, Erik

January 2007

To shed light on forces that shape the molecular evolution of bird genomes, and in turn avian adaptations, comparative analyses of avian DNA sequences are important. Moreover, contrasting findings in birds to those of other organisms will lend a clearer view on general aspects of molecular evolution. However, few such analyses have been conducted in birds. Progress is presented in this thesis. Theories predict a reduction in the mutation rate of the Z chromosome as the harmful effects of recessive mutations are exposed in female birds. We find no evidence for this. Instead, the substitution rates of sex chromosomes and autosomes are largely compatible with expectations from male-biased mutation. This suggests that a majority of mutations arise during DNA replication. Substitution rates also vary across chicken autosomes. For instance, microchromosomes accumulate ~20% more substitutions than macrochromosomes. We show that a majority of the autosomal variation in substitution rate can be accounted for by GC content, mainly due to the incidence of mutable CpG-dinucleotides. Sequence comparisons also show that the pattern of nucleotide substitution varies in the chicken genome and this reinforces regional differences in base composition. The level of selective constraint in at least some avian lineages is higher than in mammalian lineages as indicated by low dN/dS – ratios. Larger historical population sizes of birds relative to mammals could explain this observation. Within the avian genome, the dN/dS is lower for genes on micro- than macrochromosomes, potentially owing to a higher incidence of house-keeping genes in the former category. Contrasting data on non-synonymous and synonymous substitution for divergence and polymorphism shows that positive selection has contributed more to the evolution of Z-linked than autosomal genes. This is likely explained by the full exposure of beneficial recessive mutations on Z when in female birds.

Molecular genetics

Birds

molecular evolution

macrochromosomes

microchromosomes

mutation rate

substitution rate

base composition

positive selection

genetic drift

population size

Genetik

Chicken Genomics - Linkage and QTL mapping

Wahlberg, Per

January 2009

This thesis presents results from genetic studies conducted in the chicken (Gallus gallus). The domestication of chicken is believed to have been initiated approximately 7,000 – 9,000 years ago in Southeast Asia. Since that time, selective breeding has altered the appearance of the wild ancestor, creating highly specialized chicken lines developed for egg and meat production. The first part of this thesis describes a detailed genetic analysis conducted on an F2 intercross between two phenotypically diverse chicken lines. The two parental lines used in this experiment originated from the same base population and have been developed by divergent selection for juvenile body-weight. Selection during forty generations has resulted in an eight-fold difference in body-weight between the High-Weight Selected (HWS) and Low-Weight Selected (LWS) line. In an attempt to identify the genetic factors differentiating the two lines, a large intercross population was bred to map Quantitative Trait Loci (QTL) affecting body-weight traits. A linkage map was constructed which included 434 genetic markers covering 31 of the 38 chicken autosomes. Although there is a dramatic phenotypic difference between the two founder lines, the QTL analysis for marginal effect could only identify seven QTL, each with small additive effects, influencing body-weight. We extended the genetic analysis to also include a model testing for pair-wise interactions between loci (epistasis). The analysis revealed 15 QTL pairs that affect body-weight and several of those formed a network of interacting loci. These results suggest that the genetic basis for the large difference in body-weight is most likely a result of a combined effect of multiple genetic factors, including QTL with small additive effects in combination with pair-wise interactions between QTL. The second part of this thesis presents two linkage maps. The first map constructed was of the chicken Z chromosome, the second used a genome-wide marker set, including 12,945 SNP markers, to build an updated consensus map of the chicken genome. The resulting consensus map includes 9,268 genetic markers and covers 33 chromosomes, still leaving five microchromosomes without marker coverage. The genome average rate of recombination was estimated to 3.1 cM/Mb, but varied considerably between and within chromosomes. A general trend of elevated recombination rates towards telomeric ends and lower rates near centromeres was observed. This was in concordance to previous reports from mammalian species. Recombination rates in chicken were also found to be highly positively correlated with GC-rich sequences.

chicken

quantitative genetics

linkage map

QTL mapping

recombination

long-term selection

Z chromosome

selective sweep

SNP

Genetics

Genetik

Investigation of Mechanics of Mutation and Selection by Comparative Sequencing

Zody, Michael C.

January 2009

The process of evolution is of both scientific and medical interest. This thesis presents several studies using complete genomic reference sequences, comparative genomic data, and intraspecific diversity data to study the two key processes of evolution: mutation and selection. Large duplications, deletions, inversions, and translocations of DNA contribute to genomic variation both between and within species. Human chromosomes 15 and 17 contain a high percentage of dispersed, recently duplicated sequences. Examination of the relationships between these sequences showed that the majority of all duplications within each chromosome could be linked through core sequences that are prone to duplication. Comparison to orthologous sequences in other mammals allowed a reconstruction of the ancestral state of the human chromosomes, revealing that regions of rearrangement specific to the human lineage are highly enriched in chromosome-specific duplications. Comparison to copy number variation data from other studies also shows that these regions are enriched in current human structural variation. One specific region, the MAPT locus at 17q21.31, known to contain an inversion polymorphism in Europeans, was resequenced completely across both human orientation haplotypes and in chimpanzee and orangutan, revealing complex duplication structures at the inversion breakpoints, with the human region being more complex than chimpanzee or orangutan. Fluorescent in-situ hybridization analysis of human, chimpanzee, and orangutan chromosomes showed inversion polymorphisms of independent origin in all three species, demonstrating that this region has been a hotspot of genomic rearrangement for at least twelve million years. These results reveal a mechanistic relationship between sequence duplication and rearrangement in the great apes. We also generated a draft sequence of the chimpanzee genome and compared it to that of the human. Among other findings, this showed that CpG dinucleotides contribute 25% of all single base mutations, with a rate of mutation ~10-fold that of other bases, and that the male mutation rate in great apes is ~5-6 times the female rate, a higher ratio than had been observed in comparisons of primates and rodents. We detected six regions of probable recent positive selection in humans with a statistical method relying on chimpanzee sequence to control for regional variation in mutation rates. Finally, resequencing of several lines of domestic chicken and comparison to the reference chicken genome identified a number of gene deletions fixed in domestic lines and also several potential selective sweeps. Of particular interest are a missense mutation in TSHR nearly fixed in all domestic chickens and a partial deletion of SH3RF2 fixed in a high growth line. The TSHR mutation may play a role in relaxation of seasonal reproduction. A high-resolution QTL mapping experiment showed that the SH3RF2 deletion is significantly associated with increased growth. This work provides important new insights into the mechanics of evolutionary change at both the single nucleotide and structural level and identifies potential targets of natural and artificial selection in humans and chickens.

chicken

chimpanzee

human

evolution

segmental duplication

structural variation

chromosomal rearrangement

comparative genomics

positive selection

selective sweep

Genetics

Genetik

Genetic studies of stroke in Northern Sweden

Nilsson Ardnor, Sofie

January 2006

Stroke is a common disorder of later life with a complex etiology, including both environmental and genetic risk factors. The inherited predisposition is challenging to study due to the complexity of the stroke phenotype. Genetic studies in an isolated population have successfully identified a positional candidate gene for stroke, phosphodiesterase 4D (PDE4D). The aim of this thesis was to identify stroke susceptibility loci and positional candidate genes, taking advantage of low genetic variation in the northern Sweden population. All stroke cases were identified in a population-based stroke registry at the northern Sweden MONICA Centre. 56 families containing multiple cases of stroke and a follow up set of an additional 53 families were used for linkage studies. For association studies, 275 cases of first ever stroke together with 550 matched community controls were included. In paper I, we used a candidate region approach to investigate the PDE4D region on chromosome 5q. Linkage was obtained with a maximum allele-sharing LOD score of 2.06; P = 0.001. However, no significant association of ischemic stroke to the previously defined at-risk allele in PDE4D was observed. We next performed a genome wide linkage scan to explore new susceptibility loci for common forms of stroke (paper II). Non-parametric multipoint linkage analysis yielded allele-sharing LOD scores > 1.2 at nine locations; 1p34, 5q13, 7q35, 9q22, 9q34, 13q32, 14q32, 18p11, 20q13. The highest allele-sharing LOD score was obtained on chromosome 18p (LOD = 2.14). Fine mapping resulted in increased allele-sharing LOD scores for chromosome 5q13 and 9q22. In the follow up analysis of the nine regions, including all 109 families, the highest allele-sharing LOD scores were obtained on chromosomes 5q, 13q and 18p although none reached the initial genome wide values. In paper III, we focused on the chromosome 5q region, and further mapping and haplotype analysis in the families was performed. A common 1 cM haplotype was found to be shared among affected members of five families. In this region only the regulatory subunit 1 of phosphatidylinositol 3-kinase (PIK3R1) gene was located. Association of three single nucleotide polymorphisms in the PIK3R1 gene to common stroke was obtained in the case-control material. Finally, in paper IV, an extended pedigree containing seven families connected to common founders eight generations back was identified by genealogical analysis, and submitted to a separate genome wide scan analysis. A significant allele-sharing LOD score of 4.66 (genome wide P < 0.001) at chromosome 9q31-33 was obtained. Haplotype analysis identified a minimal common region of 3.2 cM, which was shared by four of the seven families. These four families contained all of the primary intracerebral hemorrhagic cases present in the extended pedigree. In conclusion we have replicated linkage of stroke susceptibility to the PDE4D region on chromosome 5q, but no significant association of ischemic stroke to PDE4D was observed. Linkage analysis of stroke did not identify any new major stroke loci, indicating that multiple minor susceptibility loci in addition to the previously known locus on chromosome 5q could contribute to the disease. In the chromosome 5q region a novel positional candidate gene for stroke was identified, the PIK3R1 gene. The PIK3R1 protein has several biological actions with potential roles in stroke susceptibility. Also a novel susceptibility locus for common forms of stroke at chromosome 9q was identified in a large pedigree, which may be of special importance for susceptibility to hemorrhagic stroke.

stroke

linkage

genome wide scan

susceptibility loci

association

candidade gene

PDE4D

PIK3R1

extended pedigree

Medical genetics

Medicinsk genetik

Molecular genetics of B- and T-lymphocyte development

Wikström, Ingela

January 2006

Lymphocytes are essential for the generation of specific immunity. Development of B cells in the bone marrow and T cells in the thymus have several analogous features, and are tightly regulated processes. Even though there is an increasing amount of information concerning lymphopoiesis, a lot of questions remain. The aim of this thesis has been to understand some of the molecular events that contribute to the control of lymphocyte development. Expression of the B cell receptor is an important checkpoint in B lymphocyte development. The Dµ protein is a truncated B cell receptor that can induce some of the signals elicited by full length µ, but cannot promote further B cell differentiation. In order to determine if this could stem from an impaired survival signal, we introduced Bcl-2 into RAG2 deficient Dµ transgenic mice. Analysis of these mice showed that Dµ could not support pre-B cell maturation despite extended survival of B cell precursors by Bcl-2. In addition, data from recombination competent Dµ transgenic mice demonstrated that the Dµ induced partial block is permissive for marginal zone B cell development, whereas the formation of follicular B cells is severely reduced. The bHLH family of transcription factors is known to be involved in the regulation of lymphocyte development. Whereas the roles of E2A and HEB have been well documented in both B- and T-lymphocytes, detailed knowledge concerning E2-2 is lacking. To address the role of E2-2 in B cell development, we have reconstituted mice, using E2-2 deficient fetal liver cells, and analysed the B cell compartments. We also measured mRNA expression patterns for the three E-proteins in wildtype mice. Resulting data show that, in addition to a role in B cell lineage entry, E2-2 is required for efficient expansion of pro-B cells, and also influences the follicular versus marginal zone decision. While focusing on assigning a role for E2-2 in T-cell development, we analyzed the expression of the E-proteins during this process and performed functional studies in fetal thymic organ cultures. E2-2 deficient mouse embryos were shown to display a partial block at the DN3 stage, which was not due to proliferation or apoptosis defects. In addition, analysis of expression levels of the pre-Talpha chain suggests that E2-2 may play a role in the regulation of transcription of pre-Talpha, and therefore in the assembly of the pre-T cell receptor.

lymphocyte development

Dmu protein

transcription factor

bHLH

E2-2

T cell

B cell

marginal zone

Medical genetics

Medicinsk genetik

Clinical and genetic studies of three inherited skeletal disorders

Stattin, Eva-Lena

January 2009

Mutations in genes of importance for cartilage development may lead to skeletal malformations, chondroskeletal dysfunction and increased susceptibility to degenerative joint disease. Characterization of these mutations and identification of molecular pathways for the corresponding gene products have contributed to our understanding of mechanisms regulating skeletal patterning, endochondral ossification and joint formation. A five generation family segregating autosomal dominant osteochondritis dissecans (OCD) was identified. Affected family members presented with OCD in knees, hips and elbows, short stature, and early osteoarthritis. A genome wide scan and a multipoint linkage analysis identified aggrecan (ACAN) as a prime candidate gene. DNA sequence analysis of the ACAN-gene revealed heterozygosity for a missense mutation (c.6907G>A) in affected subjects, resulting in a p.V2303M substitution in the aggrecan G3 domain C-type lectin. This domain is important for the interaction with other proteins in the cartilage extracellular matrix. To determine the effect of the V2303M substitution on secretion and interaction, we performed binding studies with recombinant mutated and wild type G3 proteins. We found decreased affinity or complete loss of interaction between V2303M aggrecan and fibulin1, fibulin2 and tenascin-R. Analysis of articular cartilage from an affected family member confirmed that V2303M aggrecan is produced and present. In search for gene mutations associated with multiple epiphyseal dysplasia (MED) we considered the ACAN-gene a likely candidate. The ACAN-gene was analysed in 39 individuals with MED and screened negative for mutations in six previously known MED genes. Sequence analysis revealed a heterozygous missense mutation (c.1448G>T) in one adult male and compound heterozygous missense mutations (c.1366T>C and c.836G>A) in a five year old boy with healthy parents, each of them carrier for one of the mutations. A large family segregating autosomal dominant brachymesophalangia and OCD in finger joints was characterised. The clinical presentation in six affected family members was consistent with the diagnosis Brachydactyly type A1, in this family characterized by shortening of the middle phalanges, short ulnar styloid process, flattening of the metacarpal heads and mild osteoarthritis. The condition may be caused by mutations in the Indian hedgehog gene (IHH) or a yet unidentified gene on chromosome 5p13. Sequence analysis of the IHH-gene in affected individuals revealed a novel C to T transition (c.472C>T) leading to a p.158Arg>Cys substitution. Residue 158 in IHH is highly conserved throughout evolution and molecular structure modelling of IHH suggests that the R158C substitution leads to a conformational change at the site of interaction with the IHH-receptor. This supports that the substitution causes Brachydactyly type A1 in this family. In summary, we report on the clinical, radiological and molecular genetic characteristics of the three skeletal disorders OCD, MED and BDA1. Our results provide a novel molecular mechanism in the pathophysiology of familial osteochondritis dissecans confirming the importance of aggrecan C-type lectin for cartilage function. We also show that ACAN-gene mutations may be associated with MED extending the spectrum of skeletal dysplasias associated with the aggrecan gene. Finally, we report on a novel missense mutation in a conserved region of the IHH-gene associated with BDA1.

skeletal disorders

osteochondritis dissecans

ACAN-gene

multiple epiphyseal dysplasia

brachydactyly type A1

IHH-gene

Medical genetics

Medicinsk genetik

Ligation-mediated Molecular Analysis of Influenza Subtypes, Splicing and Protein Glycosylation

Conze, Tim

January 2010

Binder-based assays are employed throughout the life sciences. Powerful signal amplification techniques have enabled detection of very rare molecule species diluted in simple buffers. Unspecific binding of primary binders leads to increased background in more complex samples. By requiring two recognition events, ligation-based molecular analyses provide highly specific detection of biomolecules in complex samples. We developed a highly multiplexed padlock-ligation assay targeting signature sequences in the hemagglutinin and neuraminidase genes. From a panel of 77 avian influenza isolates of all major serotypes, 97% were genotyped correctly in accordance with previous classifications by classical diagnostic methods (Paper I). Alternative splicing is an important mechanism expanding the proteome. Current analysis techniques fail to provide sequences of complete transcripts beyond the read length of sequencing instruments. We devised and implemented a strategy to compress the sequence information contained in the splicing pattern of a transcript into the presence or absence of sequence-blocks. We demonstrate that this assay yields information about the splicing patterns in thousands of transcripts from cellular cDNA (Paper II). Expression changes of mucin proteins and glycosylation structures are frequently observed from the early stages of cancer development. Expression of mucin 2 and sialyl-Tn are common features of intestinal metaplasia and gastric cancer, and are known to co-locate. Here we have developed an in situ proximity ligation assay (PLA) directed against mucin 2 and sialyl-Tn. Our study on intestinal metaplasia and gastric cancer tissue sections identified mucin 2 as a major carrier of sialyl-Tn in these conditions, and demonstrated how conveniently glycosylation of proteins can be studied by in situ PLA (Paper III). This thesis shows how the dual recognition requirement of ligation-based assays can be employed to detect target molecules with high specificity, to analyze several sequence features of nucleic acids or to study the proximity of two antigens in situ.

ligase

proximity ligation

gastric cancer

glycosylation

alternative splicing

avian influenza

padlock probe

Genetic and Molecular analysis of the Spinocerebellar ataxia type 7 (SCA7) disease gene

Jonasson, Jenni

January 2000

Spinocerebellar ataxia type 7 (SCA7) is a hereditary neurodegenerative disorder affecting the cerebellum, pons and retina. SCA7 patients present with gait ataxia and visual impairment as the main symptoms. Anticipation, commonly observed in SCA7 families, is a phenomenon where an earlier age at onset and a more severe progression of disease is seen in successive generations. In order to identify the gene responsible for SCA7, we performed linkage analysis on a Swedish SCA7 kindred. Evidence for linkage of the SCA7 disease locus to a 32 cM region on chromosome 3p12-21.1, between markers D3S1547 and D3S1274, was established. A number of neurodegenerative disorders associated with anticipation are caused by expanded (CAG)n repeats in their respective disease genes. In order to isolate the SCA7 disease gene we, therefore, screened a human infant brain stem cDNA library for CAG repeat containing clones, mapping to chromosome 3. Four candidate clones were isolated and analysed, but could all be excluded as the SCA7 disease gene. In 1997, the SCA7 disease gene was identified and, as expected, shown to harbour a CAG repeat, expanded in SCA7 patients. Analysis of the SCA7 CAG repeat region in Swedish SCA7 patients demonstrated that CAG repeat size was negatively correlated to age at onset of disease. Furthermore, patients with larger repeats presented with visual impairment, whereas patients with smaller repeats presented with ataxia as the initial symptom. SCA7 is the most common autosomal dominant cerebellar ataxia in Sweden and Finland, but rare in other populations. In order to investigate if the relatively high frequency of SCA7 in these countries is the result of a founder effect in the region, a haplotype analysis was performed on all SCA7 families available. All 7 families shared a common haplotype of at least 1.9 cM surrounding the SCA7 locus. In addition, strong linkage disequilibrium was demonstrated for marker D3S1287 closely linked to the SCA7 gene, suggesting a founder effect for the SCA7 mutation in Sweden and Finland. The function of the SCA7 protein, ataxin-7, is not known and it does not show significant homologies to any previously known proteins. In order to gain insight into the function of ataxin-7 we analysed the expression of ataxin-7 in brain and peripheral tissue from SCA7 patients and controls. In brain, expression was found to be mainly neuronal with a nuclear subcellular localisation. Ataxin-7 expression was found throughout the CNS, not restricted to sites of pathology. We also confirmed previously reported findings of neuronal intranuclear inclusions (NIls) in the brains of SCA7 patients. Based on our findings, we conclude that the cell type specific neurodegeneration in SCA7 is not due to differences in expression pattern in affected and non-affected tissue or the distribution pattern of aggregated protein.

Spinocerebellar ataxia

human genetics

linkage analysis

anticipation

CAG repeat expansion

founder effect

protein expression

ATXN7

Medical genetics

Medicinsk genetik