Phylogenetic Inference for Multidomain Proteins

Stolzer, Maureen

01 August 2011

In this thesis, I present a model of multidomain evolution with associated algorithms and software for phylogenetic analysis of multidomain families, as well as applications of this novel methodology to case-studies and the human genome. Phylogenetic analysis is of central importance to understanding the origins and evolution of life on earth. In biomedical research, molecular phylogenetics has proved an essential tool for practical applications. Current molecular phylogenetic methods are not equipped, however, to model many of the unique characteristics of multidomain families. Genes that encode this large and important class of proteins are characterized by a mosaic of sequence fragments that encode structural or functional modules, called domains. Multidomain families evolve via domain shuffling, a process that includes insertion, internal duplication, and deletion of domains. This versatile evolutionary mechanism played a transformative role in major evolutionary transitions, including the emergence of multicellular animals and the vertebrate immune system. Multidomain families are ill-suited to current methods for phylogeny reconstruction due to their mosaic composition. Different regions of the same protein may have different evolutionary histories. Moreover, a protein may contain domains that also occur in otherwise unrelated proteins. These attributes pose substantial obstacles for phylogenetic methods that require a multiple sequence alignment as input. In addition, current methods do not incorporate a model of domain shuffling and hence, cannot infer the events that occurred in the history of the family. I address this problem by treating a multidomain family as a set of co-evolving domains, each with its own history. If the family is evolving by vertical descent from a conserved set of ancestral domains, then all constituent domains will have the same phylogenetic history. Disagreement between domain tree topologies is evidence that the family evolved through processes other than speciation and gene duplication. My algorithms exploit this information to reconstruct the history of domain shuffling in the family, as well as the timing of these events and the ancestral domain composition. I have implemented these algorithms in software that outputs the most parsimonious history of events for each domain family. The software also reconstructs a composite family history, including duplications, insertions and losses of all constituent domains and ancestral domain composition. My approach is capable of more detailed and accurate reconstructions than the widely used domain architecture model, which ignores sequence variation between domain instances. In contrast, my approach is based on an explicit model of events and captures sequence variation between domain instances. I demonstrate the utility of this method through case studies of notch-related proteins, protein tyrosine kinases, and membrane-associated guanylate kinases. I further present a largescale analysis of domain shuffling processes through comparison of all pairs of domain families that co-occur in a protein in the human genome. These analyses suggest that (1) a remarkably greater amount of domain shuffling may have occurred than previously thought and (2) that it is not uncommon for the same domain architecture to arise more than once through independent events. This stands in contrast to earlier reports that convergent evolution of domain architecture is rare and suggests that incorporating sequence variation in evolutionary analyses of multidomain families is a crucial requirement for accurate inference.

phylogenetics

molecular evolution

multidomain

reconciliation

Biochemical Characterization of Human Guanylate Kinase and Mitochondrial Thymidine Kinase: Essential Enzymes for the Metabolic Activation of Nucleoside Analog Prodrugs

Khan, Nazimuddin

05 February 2015

No description available.

570

mitochondrial thymidine kinase

guanylate kinase

guanosine-inosine kinase

nucleoside analogs

small-angle X-ray scattering

microparticles

sensor

Biologie (PPN619462639)

Varicose/ Senz'Aria, A MAGUK Required for Junctional Assembly During Epithelial Morphogenesis in Drosophila

Moyer, Katherine Ellen

10 1900

Scaffolding proteins belonging to the Membrane Associated GUanylate Kinase (MAGUK) superfamily function as adaptors linking cytoplasmic and cell surface proteins to the cytoskeleton to regulate cell-cell adhesion, cell-cell communication and signal transduction. We have identified a novel Drosophila MAGUK member, Varicose (Vari), the homologue of vertebrate scaffolding protein PALS2. Similar to its vertebrate counterpart, Varicose localizes to pleated Septate Junctions (pSJs) of all embryonic, ectodermally derived epithelia and peripheral glia. In vari mutants, essential SJ proteins NeurexinIV and FasciclinIII are mislocalized basally and the cells develop a leaky paracellular seal. Localization of SJ protein Discs Large is not affected, indicating Vari is not involved in cell polarization. In addition, vari mutants display irregular tracheal tube diameters and have reduced lumenal protein accumulation suggesting involvement in tracheal morphogenesis. We found that Vari is distributed in the cytoplasm of optic lobe neuroepithelium and is required for proper ommatidial patterning. As well, Vari is expressed in a subset of neuroblasts and differentiated neurons of the nervous system. We also present a novel MAGUK function in wing hair alignment during adult morphogenesis. We conclude that Varicose is involved in scaffold assembly at the SJ and has a role in patterning adult epithelia and in nervous system development. / Thesis / Doctor of Philosophy (PhD)

scaffolding proteins

Varicose

adult morphogenesis

epithelia

nervous system development

sepate junctions

scaffold assembly