19 resultados para next generation sequencing
Resumo:
Gut microbial acquisition during the early stage of life is an extremely important event since it affects the health status of the host. In this contest the healthy properties of the genus Bifidobacterium have a central function in newborns. The aim of this thesis was to explore the dynamics of the gut microbial colonization in newborns and to suggest possible strategies to maintain or restore a correct balance of gut bacterial population in infants. The first step of this work was to review the most recent studies on the use of probiotics and prebiotics in infants. Secondly, in order to prevent or treat intestinal disorders that may affect newborns, the capability of selected Bifidobacterium strains to reduce the amount of Enterobacteriaceae and against the infant pathogen Streptococcus agalactiae was evaluated in vitro. Furthermore, the ability of several commercial fibers to stimulate selectively the growth of bifidobacterial strains was checked. Finally, the gut microbial composition in the early stage of life in response to the intrapartum antibiotic prophylaxis (IAP) against group B Streptococcus was studied using q-PCR, DGGE and next generation sequencing. The results globally showed that Bifidobacterium breve B632 strain is the best candidate for the use in a synbiotic product coupled to a mixture of two selected prebiotic fibers (galactooligosaccharides and fructooligosaccharides) for gastrointestinal disorders in infants. Moreover, the early gut microbial composition was affected by IAP treatment with infants showing lower counts of Bifidobacterium spp. and Bacteroides spp. coupled to a decrement of biodiversity of bacteria, compared to control infants. These studies have shown that IAP could affect the early intestinal balance in infants and they have paved the way to the definition of new strategies alternative to antibiotic treatment to control GBS infection in pregnant women.
Resumo:
Il carcinoma squamoso orale (CSO) è spesso preceduto da lesioni definite potenzialmente maligne tra cui la leucoplachia e il lichen ma una diagnosi precoce avviene ancora oggi in meno della metà dei casi. Inoltre spesso un paziente trattato per CSO svilupperà secondi tumori. Scopo del lavoro di ricerca è stato: 1) Studiare, mediante metodica di next generation sequencing, lo stato di metilazione di un gruppo di geni a partire da prelievi brushing del cavo orale al fine di identificare CSO o lesioni ad alto rischio di trasformazione maligna. 2) Valurare la relazione esistente tra sovraespressione di p16INK4A e presenza di HPV in 35 pazienti affetti da lichen 3) Valutare la presenza di marker istopatologici predittivi di comparsa di seconde manifestazioni tumorali 4) valutare la relazione clonale tra tumore primitivo e metastasi linfonodale in 8 pazienti mediante 2 metodiche di clonalità differenti: l’analisi di mtDNA e delle mutazioni del gene TP53. I risultati hanno mostrato: 1) i geni ZAP70 e GP1BB hanno presentato un alterato stato di metilazione rispettivamente nel 100% e nel 90,9% di CSO e lesioni ad alto rischio, mentre non sono risultati metilati nei controlli sani; ipotizzando un ruolo come potenziali marcatori per la diagnosi precoce nel CSO. 2)Una sovraespressione di p16INK4A è risultata in 26/35 pazienti affetti da lichen ma HPV-DNA è stato identificato in soli 4 campioni. Nessuna relazione sembra essere tra sovraespressione di p16INK4A e virus HPV. 3)L’invasione perineurale è risultato un marker predittivo della comparsa di recidiva locale e metastasi linfonodale, mentre lo stato dei margini chirurgici si è rilevato un fattore predittivo per la comparsa di secondi tumori primitivi 4) Un totale accordo nei risultati c’è stato tra analisi di mtDNA e analisi di TP53 e le due metodiche hanno identificato la presenza di 4 metastasi linfonodali non clonalmente correlate al tumore primitivo.
Resumo:
The aim of this work was to identify markers associated with production traits in the pig genome using different approaches. We focused the attention on Italian Large White pig breed using Genome Wide Association Studies (GWAS) and applying a selective genotyping approach to increase the power of the analyses. Furthermore, we searched the pig genome using Next Generation Sequencing (NSG) Ion Torrent Technology to combine selective genotyping approach and deep sequencing for SNP discovery. Other two studies were carried on with a different approach. Allele frequency changes for SNPs affecting candidate genes and at Genome Wide level were analysed to identify selection signatures driven by selection program during the last 20 years. This approach confirmed that a great number of markers may affect production traits and that they are captured by the classical selection programs. GWAS revealed 123 significant or suggestively significant SNP associated with Back Fat Thickenss and 229 associated with Average Daily Gain. 16 Copy Number Variant Regions resulted more frequent in lean or fat pigs and showed that different copies of those region could have a limited impact on fat. These often appear to be involved in food intake and behavior, beside affecting genes involved in metabolic pathways and their expression. By combining NGS sequencing with selective genotyping approach, new variants where discovered and at least 54 are worth to be analysed in association studies. The study of groups of pigs undergone to stringent selection showed that allele frequency of some loci can drastically change if they are close to traits that are interesting for selection schemes. These approaches could be, in future, integrated in genomic selection plans.
Resumo:
Today, third generation networks are consolidated realities, and user expectations on new applications and services are becoming higher and higher. Therefore, new systems and technologies are necessary to move towards the market needs and the user requirements. This has driven the development of fourth generation networks. ”Wireless network for the fourth generation” is the expression used to describe the next step in wireless communications. There is no formal definition for what these fourth generation networks are; however, we can say that the next generation networks will be based on the coexistence of heterogeneous networks, on the integration with the existing radio access network (e.g. GPRS, UMTS, WIFI, ...) and, in particular, on new emerging architectures that are obtaining more and more relevance, as Wireless Ad Hoc and Sensor Networks (WASN). Thanks to their characteristics, fourth generation wireless systems will be able to offer custom-made solutions and applications personalized according to the user requirements; they will offer all types of services at an affordable cost, and solutions characterized by flexibility, scalability and reconfigurability. This PhD’s work has been focused on WASNs, autoconfiguring networks which are not based on a fixed infrastructure, but are characterized by being infrastructure less, where devices have to automatically generate the network in the initial phase, and maintain it through reconfiguration procedures (if nodes’ mobility, or energy drain, etc..., cause disconnections). The main part of the PhD activity has been focused on an analytical study on connectivity models for wireless ad hoc and sensor networks, nevertheless a small part of my work was experimental. Anyway, both the theoretical and experimental activities have had a common aim, related to the performance evaluation of WASNs. Concerning the theoretical analysis, the objective of the connectivity studies has been the evaluation of models for the interference estimation. This is due to the fact that interference is the most important performance degradation cause in WASNs. As a consequence, is very important to find an accurate model that allows its investigation, and I’ve tried to obtain a model the most realistic and general as possible, in particular for the evaluation of the interference coming from bounded interfering areas (i.e. a WiFi hot spot, a wireless covered research laboratory, ...). On the other hand, the experimental activity has led to Throughput and Packet Error Rare measurements on a real IEEE802.15.4 Wireless Sensor Network.