Insights into the comparative biological roles of S. cerevisiae nucleoplasmin-like FKBPs Fpr3 and Fpr4

Savic, Neda

07 January 2020

The nucleoplasmin (NPM) family of acidic histone chaperones and the FK506-binding (FKBP) peptidyl proline isomerases are both linked to chromatin regulation. In vertebrates, NPM and FKBP domains are found on separate proteins. In fungi, NPM-like and FKBP domains are expressed as a single polypeptide in nucleoplasmin-like FKBP (NPL-FKBP) histone chaperones. Saccharomyces cerevisiae has two NPL-FKBPs: Fpr3 and Fpr4. These paralogs are 72% similar and are clearly derived from a common ancestral gene. This suggests that they may have redundant functions. Their retention over millions of years of evolution also implies that each must contribute non-redundantly to organism fitness. The redundant and separate biological functions of these chromatin regulators have not been studied. In this dissertation I take a systems biology approach to fill this knowledge gap. First, I refine the powerful synthetic genetic array (SGA) method of annotating gene-gene interactions, making it amenable for the analyses of paralogous genes. Using these ‘paralog-SGA’ screens I define distinct genetic interactions unique to either Fpr3 or Fpr4, shared genetic interactions common to both paralogs, and masked genetic interactions which are direct evidence for processes where these enzymes are functionally redundant. I provide transcriptomic evidence that Fpr3 and Fpr4 cooperate to regulate genes involved in polyphosphate metabolism and ribosome biogenesis. I identify an important role for Fpr4 at the 5’ ends of protein coding genes and the non-transcribed spacers of ribosomal DNA. Finally, I show that yeast lacking Fpr4 exhibit a genome instability phenotype at rDNA, implying that this histone chaperone regulates chromatin structure and DNA access at this locus. Collectively, these data demonstrate that Fpr3 and Fpr4 operate separately, cooperatively and redundantly to regulate a variety of chromatin environments. This work is the first comprehensive and comparative study of NPL-FKBP chaperones and as such represents a significant contribution to our understanding of their biological functions. / Graduate

chromatin

histone chaperones

paralog

genetic interactions

nucleolus

Especificação formal e implementação de um protótipo para a linguagem paralog

Ferreira, Simone Nasser Matos

25 October 2010

No description available.

Teses

Design and synthesis of inhibitors targeting methyllysine reader proteins belonging to the polycomb paralog family

Milosevich, Natalia

06 June 2019

Methyl reader proteins recognize and bind to post-translationally methylated residues and have functional roles in diverse cellular processes including gene regulation, development and oncogenesis. The CBX polycomb paralog family of methyllysine readers recognize trimethyllysine lysine residues on histone tail 3 and repress transcription by compacting chromatin. The polycomb paralogs form multi-protein complexes that silence the expression of tumour suppressor genes, and play important roles in regulating cell cycle and differentiation. Each paralog is structurally similar, yet has distinct functions, of which many are unknown. My work has focused on the design and synthesis of CBX inhibitors and on the development of new methodologies for the discovery of inhibitors targeting methyllysine readers. In this work, I report on a series of potent peptidic inhibitors that selectively target the CBX polycombs, as well as the first selective inhibitor for the family member CBX6, and dual-active inhibitors that target CBX6/CBX8. The results demonstrate the potential to achieve selectivity through interactions outside of the methyllysine binding domain. Structural determinants in the binding pocket of each protein that differ within the family and give rise to selectivity were discovered. I will also report on a series of peptidomimetic CBX inhibitors that are active in cells. Cellular active inhibitors are critical for understanding the biological role of each CBX protein and their potential as therapeutic targets. New high-throughput approaches are needed to efficiently target methyllysine readers by chemical inhibition. I describe in this work a strategy for creating massive libraries of phage-displayed peptidic inhibitors containing methyllysine mimics. Synthetic optimization on cysteine-containing peptide phage constructs allowed for the successful installation of Kme3 mimics. This is the first report of a post-translational methylated peptide phage library. The methodology I developed can be used in a synthetic chemistry-driven adaptation of traditional phage display for the screening of millions of peptide-based compounds. Strategies that allow for diversity and high throughput screening will aid in future efforts in targeting the highly similar CBX proteins. / Graduate / 2021-06-01

epigenetics

peptidomimetics

polycomb paralog proteins

methyllysine reader proteins

Porins of Borrelia burgdorferi

Pinne, Marija

January 2006

Borrelia burgdorferi is a pathogenic spirochete which cycles between its arthropod vector and vertebrate host. If transmitted to humans, B. burgdorferi causes Lyme disease, an infection which can impair different organs, such as the skin, joints, nervous system and heart. Alterations in protein expression due to the different environments Borrelia encounters during its complicated life cycle require advanced adaptation mechanisms. The outer surface-exposed proteins play a critical role in survival and pathogenesis of Borrelia in different hosts and tissues, being involved in avoiding the host immune response, adhesion to different tissues and nutrient acquisition. This thesis aimed to characterize integral outer membrane proteins which play a role in solute and nutrient uptake, and provides support for their role in the environmental adaptation of Borrelia. In this thesis, three B. burgdorferi proteins, P13, BBA01 and P66, were shown to be porins, and characterized structurally and functionally using a combination of biochemical, biophysical and genetic methods. The channel-forming function of the 13 kDa protein, P13, was elucidated by a lipid bilayer assay. Post-translational processing of P13 occurred at the C-terminus by C-terminal processing protease (CtpA)-dependent cleavage. The membrane-spanning architecture of P13 was determined by epitope mapping and computer-based structural predictions which revealed that P13 is an unusual porin, not possessing the structural properties of conventional porins: rather than forming β-barrels, it is predicted to span the membrane with hydrophobic α-helices. p13 belongs to a paralogous gene family. The transcription of p13 and other gene family members during in vitro growth and in a mouse infection model was therefore investigated. The paralog BBA01, which has the highest sequence homology to P13, is expressed during in vitro growth in all three Lyme disease causing species, although at very low levels. Like P13, BBA01 is also processed by CtpA and exhibits very similar channel-forming activity. Furthermore, in the absence of P13, a proportion of total BBA01 protein is relocated to the bacterial surface with strong indications that BBA01 and P13 are functionally interchangeable. P66, an integrin binding protein, was also determined to be a porin. The oligomeric state of native P66, elucidated by chemical cross-linking, indicated that P66 forms trimers, as do the majority of conventional porins. Electron crystallography and a projection map of P66 crystals at 2.2 nm resolution revealed tetragonal unit cell symmetry with the area intercalated between the assembled protein structures consistent with the approximate expected size of the channel formed by P66. Finally, the biological relevance of two porins, P13 and P66, was demonstrated in a double mutant displaying a stress response as revealed by increased sensitivity to high osmolarity and elevated expression of the B. burgdorferi heat-shock protein HtrA homolog.

Lyme disease

P13

paralog

P66

channel-forming activity

porin

Medical microbiology

Medicinsk mikrobiologi

The evolution of LOL, the secondary metabolite gene cluster for insecticidal loline alkaloids in fungal endophytes of grasses.

Kutil, Brandi Lynn

15 May 2009

LOL is a novel secondary metabolite gene cluster associated with the production of loline alkaloids (saturated 1-aminopyrrolizidine alkaloids with an oxygen bridge) exclusively in closely related grass-endophyte species in the genera Epichloë and Neotyphodium. In this study I characterize the LOL cluster in E. festucae, including the presentation of sequence corresponding to 10 individual lol genes as well as defining the boundaries of the cluster and evaluation of the genomic DNA region flanking LOL in E. festucae. In addition to characterizing the LOL cluster in E. festucae, I present LOL sequence from two additional species, Neotyphodium coenophialum and Neotyphodium sp. PauTG-1. Together with two recently published LOL clusters from N. uncinatum, these data allow for a powerful phylogenetic comparison of five clusters from four closely related species. There is a high degree of microsynteny (conserved gene order and orientation) among the five LOL clusters, allowing us to predict potential transcriptional co-regulatory binding motifs in lol promoter regions. The relatedness of LOL clusters is especially interesting in light of the history of interspecific hybridizations that generated the asexual, Neotyphodium lineages. In fact, three of the clusters appear to have been introduced to different Neotyphodium species by the same ancestral Epichloë species, for which present day isolates are no longer able to produce lolines. To address the evolutionary origins of the cluster we have investigated the phylogenetic relationships of particular lol ORFs to their paralogous primary metabolism genes (and gene families) from endophytes, other fungi and even other kingdoms. I present extensive evidence that at least two individual lol genes have evolved from primary metabolism genes within the fungal ancestors of endophytes, rather than being introduced via horizontal gene transfer. I also present complementation studies in Neurospora crassa exploring the functional divergence of one lol gene from its primary metabolism paralog. While it is clear that these insecticidal compounds should convey a selective advantage to the fungus and its host, thus explaining preservation of the trait, this analysis provides an exploration into the evolutionary origin and maintenance of the genes that comprise the LOL and the cluster itself.

Gene family evolution

Epichloe festucae Neotyphodium spp.

Neurospora crassa spe-1

ornithine decarboxylase

ortholog/paralog gene tree

PhyloCon motif

The evolution of LOL, the secondary metabolite gene cluster for insecticidal loline alkaloids in fungal endophytes of grasses.

Kutil, Brandi Lynn

15 May 2009

LOL is a novel secondary metabolite gene cluster associated with the production of loline alkaloids (saturated 1-aminopyrrolizidine alkaloids with an oxygen bridge) exclusively in closely related grass-endophyte species in the genera Epichloë and Neotyphodium. In this study I characterize the LOL cluster in E. festucae, including the presentation of sequence corresponding to 10 individual lol genes as well as defining the boundaries of the cluster and evaluation of the genomic DNA region flanking LOL in E. festucae. In addition to characterizing the LOL cluster in E. festucae, I present LOL sequence from two additional species, Neotyphodium coenophialum and Neotyphodium sp. PauTG-1. Together with two recently published LOL clusters from N. uncinatum, these data allow for a powerful phylogenetic comparison of five clusters from four closely related species. There is a high degree of microsynteny (conserved gene order and orientation) among the five LOL clusters, allowing us to predict potential transcriptional co-regulatory binding motifs in lol promoter regions. The relatedness of LOL clusters is especially interesting in light of the history of interspecific hybridizations that generated the asexual, Neotyphodium lineages. In fact, three of the clusters appear to have been introduced to different Neotyphodium species by the same ancestral Epichloë species, for which present day isolates are no longer able to produce lolines. To address the evolutionary origins of the cluster we have investigated the phylogenetic relationships of particular lol ORFs to their paralogous primary metabolism genes (and gene families) from endophytes, other fungi and even other kingdoms. I present extensive evidence that at least two individual lol genes have evolved from primary metabolism genes within the fungal ancestors of endophytes, rather than being introduced via horizontal gene transfer. I also present complementation studies in Neurospora crassa exploring the functional divergence of one lol gene from its primary metabolism paralog. While it is clear that these insecticidal compounds should convey a selective advantage to the fungus and its host, thus explaining preservation of the trait, this analysis provides an exploration into the evolutionary origin and maintenance of the genes that comprise the LOL and the cluster itself.

Gene family evolution

Epichloe festucae Neotyphodium spp.

Neurospora crassa spe-1

ornithine decarboxylase

ortholog/paralog gene tree

PhyloCon motif

Mechanism of pFGE and FGE Retention in Endoplasmic Reticulum / Mechanismus der retention von pFGE und FGE im Endoplasmatischen Reticulum

Gande, Santosh Lakshmi

16 January 2007

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

Endoplasmatischen Reticulum

Protein Retention

KDEL

Formylglycin bildende Enzym FGE

paraloges FGE

Sulfatasen.

Endoplasmic reticulum

protein retention

KDEL

formylglycine generating enzyme FGE

paralog of FGE

Sulfatases.

42.00 Biologie: Allgemeines

Biologie

Fylogeneze krvetvorby obratlovců / Origins of vertebrate hematiopoiesis

Svoboda, Ondřej

January 2015

(ENGLISH) Hematopoiesis is dependent on the actions of hematopoietic stem cells (HSCs). This process is tightly controlled through a complex array of extrinsic and intrinsic factors. Even though the hematopoiesis seems to be well conserved across the disparate vertebrate animals, erythroid and thrombocytic differentiation have changed during the evolution of mammals. Specifically, adult mammalian red blood cells have the unique feature of being enucleated, and mammalian thrombocytes are not individual cells, but fragments of megakaryocytes, instead. It is likely that these enhancements provided a survival advantage to early mammalian species; however, they also bring up the question of evolutionary origin of these cells that studied using zebrafish (Danio rerio) model. First, it was necessary to generate a toolbox of a recombinant cytokines and optimized culture media that allowed us to manipulate zebrafish hematopoietic cells ex vivo in liquid and clonal cultures. Interestingly, teleost species underwent an extra duplication event during their evolution and as a result, two copies (paralogs) of some of the genes are present in zebrafish. This was also the case for majority of the cytokines from our toolbox and here, we provide functional characterization of these paralogs. Strikingly, our results...