Peptidoglycan Recognition Proteins : Major Regulators of Drosophila Immunity

Mellroth, Peter

January 2005

All eukaryotic organisms have an innate immune system characterized by germ-line encoded receptors and effector molecules, which mediate detection and clearance of microbes such as bacteria, fungi, and parasites. VertebrateDrosophila as a genetically tractable organism with a This thesis concerns the peptidoglycan recognition protein (PGRP) gene family in the fruit fly. The family consists of thirteen genes, of which a few have been reported to be part of the signaling pathways that regulates immune Data presented show that the putative receptors have affinity for peptidoglycan, but not for lipopolysaccharide, or the fungal cell wall polymer beta-glucan. PGRP-SA, receptor of the Toll pathway, has a preference for In a search for novel PGRP receptors I found two PGRP proteins that instead displayed enzymatic activity towards peptidoglycan. They are of the N-actylmuramoyl L-alanine amidase type, which degrades peptidoglycan by splittingStaphylococcus aureus peptidoglycan looses its immune elicitor capacity. This is in contrast to lysozyme-degraded peptidoglycan, which isDrosophila PGRPs to be potential enzymes. PGRP-SB1 is the other enzymatic PGRP described within this thesis. It has a moreBacillus megaterium. In conclusion, receptor PGRP proteins binds bacterial peptidoglycan and triggers immune gene pathways and enzymatic PGRPs have the capacity to reduce the elicitor property of peptidoglycan.

Innate immunity

peptidoglycan recognition protein

PGRP

Toll

Imd

Drosophila immunity

Microbiology and immunology

Mikrobiologi och immunologi

Immune responses of the insect Manduca sexta towards the bacterium Photorhabdus luminescens

Millichap, Peter

January 2008

The Gram-negative bacterium Photorhabdus luminescens is a pathogen of insects. It is able to secrete a variety of toxins and effectors against its host in order to escape its immune defences. The model insect Manduca sexta is able to mount a variety of humoral and cellular responses against pathogen attack. Ultimately these prove ineffective against P. luminescens. The pre-treatment of M. sexta with Escherichia coli provides protection against the pathogenesis of P. luminescens. Here, I use RNA interference and Fluorescence-assisted cell sorting techniques to investigate interactions between pathogen and host to further elucidate the roles of various host factors in mounting the immune response. I also investigate the nutrient requirements of the bacteria for pathogenesis. I show data that peptidoglycan recognition protein (PGRP) is essential for the up-regulation of antimicrobial peptides, an important immune defence. I also show that P. luminescens has a requirement for two types of iron during pathogenesis of M. sexta. And lastly I show that P. luminescens is able to avoid phagocytosis, another important immune defence.

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