Análise de polimorfismos dos genes KIR e HLA em pacientes com vitiligo

Dias, Vanessa Guterres

January 2014

O vitiligo é uma doença dermatológica de causa desconhecida. O aparecimento se dá através de manchas branco-nacaradas na pele, ocorridas pela morte ou redução na funcionalidade das células epidérmicas, os melanócitos, que produzem a melanina, pigmento cutâneo. As células Natural Killer (NK) fazem parte do sistema imune inato e através de seus receptores KIR (Killer immunoglobulin-like-receptors) reconhecem moléculas de HLA (Human leukocyte antigen) classe I presentes nas células. Quando não há o reconhecimento do HLA classe I, como em células tumorais ou infectadas por vírus, a célula NK induz a morte da célula alvo. Uma das teorias para essa doença é a imunológica, a qual admite que o vitiligo seja doença autoimune pela formação de anticorpos antimelanócitos, podendo ser associado a outras doenças autoimunes. O objetivo deste estudo foi investigar polimorfismos dos genes KIR e HLA e sua associação com pacientes com vitiligo comparando com um grupo controle. Foram genotipados 112 pacientes com diagnóstico de vitiligo e 250 indivíduos saudáveis para 16 genes KIR e seus ligantes HLA por PCR-SSO e PCR-SSP respectivamente. Nossos resultados mostraram um fator de risco para a doença na interação do gene ativador KIR2DS1 com o seu ligante C2 (P=0,015; OR: 2,06). Também houve uma associação significativa do gene ativador KIR2DS1 com o ligante heterozigoto C1/C2 (P=0,025; OR: 2,26). A interação KIR2DS1/C2 está presente em 52,8% dos pacientes com vitiligo e em 35,2% do grupo controle, já a interação KIR2DS1/C1/C2 está presente em 54,7% dos pacientes com vitiligo e 34,9% do grupo controle. Nossos resultados sugerem um possível fator de risco do gene ativador KIR2DS1 com o seu ligante C2, sendo essa combinação uma possível susceptibilidade à doença. / Vitiligo is a skin disease of unknown cause. The main symptom of vitiligo is white patches on the skin. Which are caused by destruction of pigment-forming cells (melanocytes). Natural killer (NK) cells are part of the innate immune system and they recognize class I HLA molecules (human leukocyte antigen) through their KIR receptors (killer-cell immunoglobulin-like-receptors). When class I HLA molecules are not recognized, e.g.: tumour cells or virus-infected cells, NK cells induce the death of target cells. One of the possible aetiologies for this disease is the immune cause. According to this theory, vitiligo is an autoimmune disease caused by the production of anti-melanocyte antibodies and it may be associated with other autoimmune diseases. The objective of the present study was to investigate KIR and HLA gene polymorphisms and their association with vitiligo comparing with a control group. We genotyped 112 patients diagnosed with vitiligo and 250 healthy individuals for 16 KIR genes and their HLA ligands using PCR-SSO and PCR-SSP respectively. Our findings showed a risk factor for vitiligo in the interaction between the activating KIR2DS1 gene and its C2 ligand (P=0.015; OR: 2.06). There was also a significant association of the activating KIR2DS1 gene with the heterozygous C1/C2 ligand (P=0.025; OR: 2.26). The KIR2DS1/C2 interaction was found in 52.8% of vitiligo patients and in 35.2% of the control group; whereas the KIR2DS1/C1/C2 interaction was found in 54.7% of vitiligo patients and 34.9% of the control group. These findings suggest a possible risk factor related to the interaction between the activating KIR2DS1 gene and its C2 ligand, since this combination may be a disease susceptibility factor.

Vitiligo

Polimorfismo genético

Células matadoras naturais

HLA gene

KIR gene

NK cell

Análise de polimorfismos dos genes KIR e HLA em pacientes com vitiligo

Dias, Vanessa Guterres

January 2014

O vitiligo é uma doença dermatológica de causa desconhecida. O aparecimento se dá através de manchas branco-nacaradas na pele, ocorridas pela morte ou redução na funcionalidade das células epidérmicas, os melanócitos, que produzem a melanina, pigmento cutâneo. As células Natural Killer (NK) fazem parte do sistema imune inato e através de seus receptores KIR (Killer immunoglobulin-like-receptors) reconhecem moléculas de HLA (Human leukocyte antigen) classe I presentes nas células. Quando não há o reconhecimento do HLA classe I, como em células tumorais ou infectadas por vírus, a célula NK induz a morte da célula alvo. Uma das teorias para essa doença é a imunológica, a qual admite que o vitiligo seja doença autoimune pela formação de anticorpos antimelanócitos, podendo ser associado a outras doenças autoimunes. O objetivo deste estudo foi investigar polimorfismos dos genes KIR e HLA e sua associação com pacientes com vitiligo comparando com um grupo controle. Foram genotipados 112 pacientes com diagnóstico de vitiligo e 250 indivíduos saudáveis para 16 genes KIR e seus ligantes HLA por PCR-SSO e PCR-SSP respectivamente. Nossos resultados mostraram um fator de risco para a doença na interação do gene ativador KIR2DS1 com o seu ligante C2 (P=0,015; OR: 2,06). Também houve uma associação significativa do gene ativador KIR2DS1 com o ligante heterozigoto C1/C2 (P=0,025; OR: 2,26). A interação KIR2DS1/C2 está presente em 52,8% dos pacientes com vitiligo e em 35,2% do grupo controle, já a interação KIR2DS1/C1/C2 está presente em 54,7% dos pacientes com vitiligo e 34,9% do grupo controle. Nossos resultados sugerem um possível fator de risco do gene ativador KIR2DS1 com o seu ligante C2, sendo essa combinação uma possível susceptibilidade à doença. / Vitiligo is a skin disease of unknown cause. The main symptom of vitiligo is white patches on the skin. Which are caused by destruction of pigment-forming cells (melanocytes). Natural killer (NK) cells are part of the innate immune system and they recognize class I HLA molecules (human leukocyte antigen) through their KIR receptors (killer-cell immunoglobulin-like-receptors). When class I HLA molecules are not recognized, e.g.: tumour cells or virus-infected cells, NK cells induce the death of target cells. One of the possible aetiologies for this disease is the immune cause. According to this theory, vitiligo is an autoimmune disease caused by the production of anti-melanocyte antibodies and it may be associated with other autoimmune diseases. The objective of the present study was to investigate KIR and HLA gene polymorphisms and their association with vitiligo comparing with a control group. We genotyped 112 patients diagnosed with vitiligo and 250 healthy individuals for 16 KIR genes and their HLA ligands using PCR-SSO and PCR-SSP respectively. Our findings showed a risk factor for vitiligo in the interaction between the activating KIR2DS1 gene and its C2 ligand (P=0.015; OR: 2.06). There was also a significant association of the activating KIR2DS1 gene with the heterozygous C1/C2 ligand (P=0.025; OR: 2.26). The KIR2DS1/C2 interaction was found in 52.8% of vitiligo patients and in 35.2% of the control group; whereas the KIR2DS1/C1/C2 interaction was found in 54.7% of vitiligo patients and 34.9% of the control group. These findings suggest a possible risk factor related to the interaction between the activating KIR2DS1 gene and its C2 ligand, since this combination may be a disease susceptibility factor.

Vitiligo

Polimorfismo genético

Células matadoras naturais

HLA gene

KIR gene

NK cell

Análise de polimorfismos dos genes KIR e HLA em pacientes com vitiligo

Dias, Vanessa Guterres

January 2014

O vitiligo é uma doença dermatológica de causa desconhecida. O aparecimento se dá através de manchas branco-nacaradas na pele, ocorridas pela morte ou redução na funcionalidade das células epidérmicas, os melanócitos, que produzem a melanina, pigmento cutâneo. As células Natural Killer (NK) fazem parte do sistema imune inato e através de seus receptores KIR (Killer immunoglobulin-like-receptors) reconhecem moléculas de HLA (Human leukocyte antigen) classe I presentes nas células. Quando não há o reconhecimento do HLA classe I, como em células tumorais ou infectadas por vírus, a célula NK induz a morte da célula alvo. Uma das teorias para essa doença é a imunológica, a qual admite que o vitiligo seja doença autoimune pela formação de anticorpos antimelanócitos, podendo ser associado a outras doenças autoimunes. O objetivo deste estudo foi investigar polimorfismos dos genes KIR e HLA e sua associação com pacientes com vitiligo comparando com um grupo controle. Foram genotipados 112 pacientes com diagnóstico de vitiligo e 250 indivíduos saudáveis para 16 genes KIR e seus ligantes HLA por PCR-SSO e PCR-SSP respectivamente. Nossos resultados mostraram um fator de risco para a doença na interação do gene ativador KIR2DS1 com o seu ligante C2 (P=0,015; OR: 2,06). Também houve uma associação significativa do gene ativador KIR2DS1 com o ligante heterozigoto C1/C2 (P=0,025; OR: 2,26). A interação KIR2DS1/C2 está presente em 52,8% dos pacientes com vitiligo e em 35,2% do grupo controle, já a interação KIR2DS1/C1/C2 está presente em 54,7% dos pacientes com vitiligo e 34,9% do grupo controle. Nossos resultados sugerem um possível fator de risco do gene ativador KIR2DS1 com o seu ligante C2, sendo essa combinação uma possível susceptibilidade à doença. / Vitiligo is a skin disease of unknown cause. The main symptom of vitiligo is white patches on the skin. Which are caused by destruction of pigment-forming cells (melanocytes). Natural killer (NK) cells are part of the innate immune system and they recognize class I HLA molecules (human leukocyte antigen) through their KIR receptors (killer-cell immunoglobulin-like-receptors). When class I HLA molecules are not recognized, e.g.: tumour cells or virus-infected cells, NK cells induce the death of target cells. One of the possible aetiologies for this disease is the immune cause. According to this theory, vitiligo is an autoimmune disease caused by the production of anti-melanocyte antibodies and it may be associated with other autoimmune diseases. The objective of the present study was to investigate KIR and HLA gene polymorphisms and their association with vitiligo comparing with a control group. We genotyped 112 patients diagnosed with vitiligo and 250 healthy individuals for 16 KIR genes and their HLA ligands using PCR-SSO and PCR-SSP respectively. Our findings showed a risk factor for vitiligo in the interaction between the activating KIR2DS1 gene and its C2 ligand (P=0.015; OR: 2.06). There was also a significant association of the activating KIR2DS1 gene with the heterozygous C1/C2 ligand (P=0.025; OR: 2.26). The KIR2DS1/C2 interaction was found in 52.8% of vitiligo patients and in 35.2% of the control group; whereas the KIR2DS1/C1/C2 interaction was found in 54.7% of vitiligo patients and 34.9% of the control group. These findings suggest a possible risk factor related to the interaction between the activating KIR2DS1 gene and its C2 ligand, since this combination may be a disease susceptibility factor.

Vitiligo

Polimorfismo genético

Células matadoras naturais

HLA gene

KIR gene

NK cell

ESTUDO DA ASSOCIAÇÃO DOS GENES HLA-A*, -B* E -DRB1* EM MULHERES COM ABORTAMENTO ESPONTÂNEO RECORRENTE (AER) / STUDY OF THE ASSOCIATION OF GENE HLA-A * B * E-DRB1 * IN WOMEN WITH RECURRENT SPONTANEOUS ABORTION (RSA)

Silva, Fábio França

06 April 2009

Made available in DSpace on 2016-08-19T18:16:00Z (GMT). No. of bitstreams: 1 FABIO FRANCA SILVA.pdf: 387985 bytes, checksum: b614ae131f06a658fbdac4196b4d623c (MD5) Previous issue date: 2009-04-06 / FUNDAÇÃO DE AMPARO À PESQUISA E AO DESENVOLVIMENTO CIENTIFICO E TECNOLÓGICO DO MARANHÃO / Recurrent spontaneous abortion (RSA) is defined as two or more consecutive spontaneous pregnancy losses before the 20th week of gestation, a situation that occurs in 1 to 2% of women in reproductive age. Genetic, anatomical, endocrine, infectious and immunologic factors through mechanisms that relate to the Major Histocompatibility Complex (MHC) and the presence of certain HLA (Human Leukocyte Antigens) are associated to RSA. HLA gene is located on the short arm of chromosome 6 between the 6p21.31 and 6p21.33 regions. This gene is inherited in haplotypes and expressed in codominance, having influence on modulation and induction of mother tolerance during the pregnancy. The aim of this study was to compare the allelic frequencies of HLA-A*, HLA-B* and HLA-DRB1* loci in women with and without RSA. It was a case-control study in 200 women (100 for each group) between 18 and 35 years of age. All samples were typified by the PCR-SSOP method (Polymerase Chain Reaction-Sequence Specific Oligonucleotide Probes). The most frequent alleles observed in the group of women with and without RSA were: HLAA* 02 (56%) and (49%), HLA-DRB1*13 (31%) and (39%) respectively - there was no statistical significative difference when compared among the groups for this alleles; HLA-A*24 (12%) e (25%), (OR: 0.41; 95% CI: 0.18-0.92; p=0.028); HLA-A*34 (8%) e (1%), (OR: 8.61; 95% CI: 1.06-187.04; p=0.034); HLA-B*35 (16%) e (41%) (OR: 0.27; 95% CI: 0.13 0.56; p=0.0002). The most frequent haplotypes observed in the group of women with and without RSA were: A*02DRB1*16 (12%) e (2%) (OR: 6.68; 95% CI: 1.36 44.52; p=0.012) respectively. In this research, DRB1* locus in women with RSA was in linkage disequilibrium (p=0.01.). The high frequency of HLA-A*02 and HLA-DRB1*13 alleles in this study was due to the wide distribution of this allele in the population of Maranhão. HLA-A*24 e HLA-B*35 alleles were considered as a protection factor and HLA-A*34 allele was considered as a risk factor to RSA. The A*02DRB1*16 haplotype was the most frequent and considered as a risk factor to RSA. In order to confirm the observed results in this research, a study involving a higher sample size is necessary as well as genetic epidemiology researches to shed light on the role of HLA antigens and/or its connection to other genes as a risk factor. / Abortamento Espontâneo Recorrente (AER) caracteriza-se por duas ou mais perdas conceptuais espontâneas e consecutivas antes da 20ª semana de gestação, acometendo entre 1% e 2% das mulheres em idade reprodutiva. Fatores genéticos, anatômicos, endócrinos, infecciosos e imunológicos, por meio de mecanismos que relacionam o Complexo Principal de Histocompatibilidade (CPH) e a frequência de determinados antígenos HLA (Antígeno Leucocitário Humano), estão associados ao AER. O gene HLA localiza-se no braço curto do cromossomo 6 entre as regiões 6p21.31 e 6p21.33, é herdado em bloco e expresso em co-dominância. O mesmo exerce uma grande influência na modulação e indução da tolerância materna durante a gestação. Esta pesquisa teve como objetivo verificar as frequências alélicas dos loci HLA-A*, -B* e - DRB1* em mulheres com e sem AER. Realizou-se um estudo caso-controle em 200 mulheres (100 para cada grupo), entre 18 e 35 anos de idade. Todas as amostras foram tipificadas pelo método PCR-SSOP (Reação em cadeia da Polimerase Sondas de Oligonucleotídios de Sequências Especificas). Os alelos mais frequentes tanto em mulheres com e sem AER foram, respectivamente: HLA-A*02 (56%) e (49%), HLADRB1* 13 (31%) e (39%)-embora sem resultado estatisticamente significante; HLAA* 24 (12%) e (25%), (OR: 0,41; 95% IC: 0,18-0,92; p=0,028); HLA-A*34 (8%) e (1%), (OR: 8,61; 95% IC: 1,06-187,04; p=0,034); HLA-B*35 (16%) e (41%) (OR: 0,27; 95% IC: 0,13 0,56; p=0,0002). Os haplótipos mais frequentes em mulheres com e sem AER foram, respectivamente: A*02DRB1*16 (12%) e (2%) (OR 6,68; 95% IC: 1,36 44,52; p=0,012). No presente estudo, apenas o locus DRB1* apresentou desequilíbrio de ligação significante (p=0,01) em mulheres com AER. A elevada frequência dos alelos HLA-A*02 e HLA-DRB1*13 é justificada pela ampla distribuição desses alelos na população maranhense. Os alelos HLA-A*24 e HLA-B*35 apresentaram-se como um fator de proteção e o alelo HLA-A*34 um fator de risco para AER. Para as associações haplotípicas, o haplótipo A*02DRB1*16 foi mais frequente em mulheres com AER, sendo um fator de risco para este grupo. Para a ratificação dos resultados deste trabalho, faz-se necessário aumentar o número amostral, bem como estudos de epidemiologia genética para o melhor entendimento do papel dos antígenos HLA e/ou sua ligação a outros genes como fator de risco para o AER.

AER

Aborto Espontâneo Recorrente

Frequência alélica

Gene HLA

RSA

Recurrent Miscarriage

Allelic frequency

HLA Gene

Multi-scale Modelling of HLA Diversity and Its Effect on Cytotoxic Immune Responses in Influenza H1N1 Infection

Mukherjee, Sumanta

January 2015

Cytotoxic T-lymphocytes (CTLs) are important components of the adaptive immune system and function by scanning the intracellular environment so as to detect and de-stroy infected cells. CTL responses play a major role in controlling virus-infected cells such as in HIV or influenza and cells infected with intracellular bacteria such as in tuberculosis. To do so they require the antigens to be presented to them, which is fulfilled by the major histocompatibility complex (MHC), commonly known as human leukocyte antigen or HLA molecules in humans. Recognition of antigenic peptides to Class-1 HLA molecules is a prerequisite for triggering CTL immune responses. Individuals differ significantly in their ability to respond to an infection. Among the factors that govern the outcome of an infection, HLA polymorphism in the host is one of the most important. Despite a large body of work on HLA molecules, much remains to be understood about the relationship between HLA diversity and disease susceptibility. High complexity arises due to HLA allele polymorphism, extensive antigen cross-presentability, and host-pathogen heterogeneity. A given allele can recognize a number of different peptides from various pathogens and a given peptide can also bind to a number of different individuals. Thus, given the plurality in peptide-allele pairs and the large number of alleles, understanding the differences in recognition profiles and the implications that follow for disease susceptibilities require mathematical modelling and computational analysis. The main objectives of the thesis were to understand heterogeneity in antigen presentation by HLA molecules at different scales and how that heterogeneity translates to variations in disease susceptibilities and finally the disease dynamics in different populations. Towards this goal, first the variations in HLA alleles need to be characterized systematically and their recognition properties understood. A structure-based classification of all known HLA class-1 alleles was therefore attempted. In the process, it was also of interest to see if understanding of sub-structures at the binding grooves of HLA molecules could help in high confidence prediction of epitopes for different alleles. Next, the goal was to understand how HLA heterogeneity affect disease susceptibilities and disease spread in populations. This was studied at two different levels. Firstly, modelling the HLA genotypes and CTL responses in different populations and assessing how they recognized epitopes from a given virus. The second approach involved modelling the disease dynamics given the predicted susceptibilities in different populations. Influenza H1N1 infection was used as a case study. The specific objectives addressed are: (a) To develop a classification scheme for all known HLA class-1 alleles that can explain epitope recognition profiles and further to dissect the physic-chemical features responsible for differences in peptide specificities, (b) A statistical model has been derived from a large dataset of HLA-peptide complexes. The derived model was used to identify the interdependencies of residues at different peptide and thereby, rationalize the HLA class-I allele binding specificity at a greater detail, (c) To understand the effect of HLA heterogeneity on CTL mediated disease response. A model of HLA genotypes for different populations was required for this, which was constructed and used for estimating disease response to H1N1 via the prediction of epi-topes and (d) To model disease dynamics in different populations with the knowledge of the CTL response-grouping and to evaluate the effect of heterogeneity on different vaccination strategies. Each of the four objectives listed above are described subsequently in chapters 2 to 5, followed by Chapter 6 which summarises the findings from the thesis and presents future directions. Chapter 1 presents an introduction to the importance of the function of HLA molecules, describes structural bioinformatics as a discipline and the methods that are available for it. The chapter also describes different mathematical modelling strategies available to study host immune responses. Chapter 2 describes a novel method for structure-based hierarchical classification of HLA alleles. Presently, more than 2000 HLA class-I alleles are reported, and they vary only across peptide-binding grooves. The polymorphism they exhibit, enables them to bind to a wide range of peptide antigens from diverse sources. HLA molecules and peptides present a complex molecular recognition pattern due to multiplicity in their associations. Thus, a powerful grouping scheme that not only provides an insightful classification, but is also capable of dissecting the physicochemical basis of recognition specificity is necessary to address this complexity. The study reports a hierarchical classification of 2010 class-I alleles by using a systematic divisive clustering method. All-pair distances of alleles were obtained by comparing binding pockets in the structural models. By varying the similarity thresholds, a multilevel classification with 7 supergroups was derived, each further categorized to yield a total of 72 groups. An independent clustering scheme based only on the similarities in their epitope pools correlated highly with pocket-based clustering. Physicochemical feature combinations that best explains the basis for the observed clustering are identified. Mutual information calculated for the set of peptide ligands enables identification of binding site residues that contribute to peptide specificity. The grouping of HLA molecules achieved here will be useful for rational vaccine design, understanding disease susceptibilities and predicting risk of organ transplants. The results are presented in an interactive web- server http://proline.iisc.ernet.in/hlaclassify. In Chapter 3, the knowledge of structural features responsible for generating peptide recognition specificities are first analysed and then utilized for predicting T-cell epi-topes for any class-1 HLA allele. Since identification of epitopes is critical and central to many of the questions in immunology, a study of several HLA-peptide complexes is carried out at the structural level and factors are identified that discriminate good binder peptides from those that do not. T-cell epitopes serve as molecular keys to initiate adaptive immune responses. Identification of T-cell epitopes is also a key step in rational vaccine design. Most available methods are driven by informatics, critically dependent on experimentally obtained training data. Analysis of the training set from IEDB for several alleles indicate that sampling of the peptide space is extremely sparse covering only a tiny fraction of all possible nonamer space, and also heavily skewed, thus restricting the range of epitope prediction. A new epitope prediction method is therefore developed. The method has four distinct modules, (a) structural modelling, estimating statistical pair-potentials and constraint derivation, (b) implicit modelling and interaction profiling, (c) binding affinity prediction through feature representation and (d) use of graphical models to extract peptide sequence signatures to predict epitopes for HLA class I alleles . HLaffy is a novel and efficient epitope prediction method that predicts epitopes for any HLA Class-1 allele, by estimating binding strengths of peptide-HLA complexes which is achieved through learning pair-potentials important for peptide binding. It stands on the strength of mechanistic understanding of HLA-peptide recognition and provides an estimate of the total ligand space for each allele. The method is made accessible through a webserver http://proline.biochem.iisc.ernet.in/HLaffy. In chapter 4, the effect of genetic heterogeneity on disease susceptibilities are investigated. Individuals differ significantly in their ability to respond to an infection. Among the factors that govern the outcome of an infection, HLA polymorphism in the host is one of the most important. Despite a large body of work on HLA molecules, much remains to be understood about how host HLA diversity affects disease susceptibilities. High complexity due to polymorphism, extensive cross-presentability among HLA alleles, host and pathogen heterogeneity, demands for an investigation through computational approaches. Host heterogeneity in a population is modelled through a molecular systems approach starting with mining ‘big data’ from literature. The in-sights derived through this is used to investigate the effect of heterogeneity in a population in terms of the impact it makes on recognizing a pathogen. A case study of influenza virus H1N1 infection is presented. For this, a comprehensive CTL immunome is defined by taking a consensus prediction by three distinct methods. Next, HLA genotypes are constructed for different populations using a probabilistic method. Epidemic incidences in general are observed to correlate with poor CTL response in populations. From this study, it is seen that large populations can be classified into a small number of groups called response-types, specific to a given viral strain. Individuals of a response type are expected to exhibit similar CTL responses. Extent of CTL responses varies significantly across different populations and increases with increase in genetic heterogeneity. Overall, the study presents a conceptual advance towards understanding how genetic heterogeneity influences disease susceptibility in individuals and in populations. Lists of top-ranking epitopes and proteins are also derived, ranked on the basis of conservation, antigenic cross-reactivity and population coverage, which pro- vide ready short-lists for rational vaccine design (flutope). Next, in Chapter 5, the effect of genetic heterogeneity on disease dynamics has been investigated. A mathematical framework has been developed to incorporate the heterogeneity information in the form of response-types described in the previous chap-ter. The spread of a disease in a population is a complex process, controlled by various factors, ranging from molecular level recognition events to socio-economic causes. The ‘response-typing’ described in the previous chapter allows identification of distinct groups of individuals, each with a different extent of susceptibility to a given strain of the virus. 3 different approaches are used for modelling: (i) an SIR model where different response types are considered as partitions of each S, I and R compartment. Initially SIR models are developed, such that the S compartment is sub-divided into further groups based on the ‘response-types’ obtained in the previous chapter. This analysis shows an effect in infection sweep time, i.e., how long the infection stays in the population. A stochastic model incorporates the environmental noise due to random variation in population influx, due to birth, death or migration. The system is observed to show higher stability in the presence of genetic heterogeneity. As the contagion spreads only through direct host to host contact. The topology of the contact network, plays major role in deciding the extent of disease dynamics. An agent based computational framework has been developed for modelling disease spread by considering spatial distribution of the agents, their movement patterns and resulting contact probabilities. The agent-based model (ABM) incorporates the temporal patterns of contacts. The ABM is based on a city block model and captures movement of individuals parametrically. A new concept of system ‘characteristic time’ has been introduced in context of a time-evolving network. ‘Characteristic time’ is the minimum time required to ensure, every individual is connected to all other individuals, in the time aggregated contact network. For any given temporal system, disease time must exceed ‘characteristic time’ in order to spread throughout the population. Shorter ‘characteristic time’ of the system is suggestive of faster spread of the disease. A disease spread network is constructed which shows how the disease spreads from one infected individual to others in the city, given the contact rules and their relative susceptibilities to that viral strain. A high degree of population heterogeneity is seen to results in longer disease residence time. Susceptible individuals preferentially get infected first thereby exposing more susceptible individuals to the disease. Vaccination strategies are derived from the model, which indicates that vaccinating only 20% of the agents, who are hub nodes or highly central nodes and who also have a high degree to susceptible agents, lead to high levels of herd immunity and can confer protection to the rest of the population. Overall, the thesis has provided biologically meaningful classification of all known HLA class-1 alleles and has unravelled the physico-chemical basis for their peptide recognition specificities. The thesis also presents a new algorithm for estimating pep-tide binding affinities and consequently predicting epitopes for all alleles. Finally the thesis presents a conceptual advance in relating HLA diversity to disease susceptibilities and explains how different populations can respond differently to a given infection. A case study with the influenza H1N1 virus identified populations who are most susceptible and those who are least susceptible, in the process identifying important epitopes and responder alleles, providing important pointers for vaccine design. The influence of heterogeneity and response-typing on disease dynamics is also presented for influenza H1N1 infection, which has led to the rational identification of effective vaccination strategies. The methods and concepts developed here are fairly generic and can be adapted easily for studying other infectious diseases as well. Three new web-resources, a) HLAclassify, b) HLaffy and c) Flutope have been developed, which host pre-computed results as well as allow interactive querying to an user to perform analysis with a specific allele, peptide or a pathogenic genome sequence.

Influenza H1N1 Infection

Cytotoxic T-lymphocytes (CTLs)

Human Leucocyte Antigen (HLA)

Cytotoxic Immune Responses Modeling

Human Immune System

Peptide Binding

Genetic Heterogeneity

Structural Bioinformatics

HLAClassify

HLAffy

Flutope

Disease Spreader Network (DSN)

Disease Dynamics

Mathematics