Polymerizing activity and regulation of group B Streptococcus pilus 2a sortase C1

Group B Streptococcus [GBS; Streptococcus agalactiae] is the leading cause of life-threatening diseases in newborn and is also becoming a common cause of invasive diseases in non-pregnant, elderly and immune-compromised adults. Pili, long filamentous fibers protruding from the bacterial surface, have been discovered in GBS, as important virulence factors and vaccine candidates. Gram-positive bacteria build pili on their cell surface via a class C sortase-catalyzed transpeptidation mechanism from pilin protein substrates. Despite the availability of several crystal structures, pilus-related C sortases remain poorly characterized to date and their mechanisms of transpeptidation and regulation need to be further investigated. The available three-dimensional structures of these enzymes reveal a typical sortase fold except for the presence of a unique feature represented by an N-terminal highly flexible loop, known as the “lid”. This region interacts with the residues composing the catalytic triad and covers the active site, thus maintaining the enzyme in an auto-inhibited state and preventing the accessibility to the substrate. It is believed that enzyme activation may occur only after lid displacement from the catalytic domain. In this work we provide the first direct evidence of the regulatory role of the lid, demonstrating that it is possible to obtain in vitro an efficient polymerization of pilin subunits using an active C sortase lid mutant carrying a single residue mutation in the lid region. Moreover, biochemical analyses of this recombinant mutant reveal that the lid confers thermodynamic and proteolytic stability to the enzyme. A further characterization of this sortase active mutant showed promiscuity in the substrate recognition, as it is able to polymerize different LPXTG-proteins in vitro.

Lysosomaler Transport kationischer Aminosäuren durch Mitglieder der SLC7-Familie

Lysosomaler Transport kationischer Aminosäuren (KAS) stellt einen Rettungsweg in der Cystinose-Therapie dar. Ein solches Transportsystem wurde in humanen Hautfibroblasten beschrieben und mit System c benannt. Des Weiteren stellt lysosomales Arginin eine Substratquelle für die endotheliale NO-Synthase (eNOS) dar. Das von der eNOS gebildete NO ist ein wichtiges vasoprotektiv wirkendes Signalmolekül. Ziel war es daher, herauszufinden, ob Mitglieder der SLC7-Unterfamilie hCAT möglicherweise System c repräsentieren.rnIn dieser Arbeit konnte ich die lysosomale Lokalisation verschiedener endogener, sowie als EGFP-Fusionsproteine überexprimierter CAT-Isoformen nachweisen. Mittels Fluoreszenz-mikroskopie wurde festgestellt, dass die in U373MG-Zellen überexprimierten Fusionsproteine hCAT-1.EGFP sowie SLC7A14.EGFP mit dem lysosomalen Fluoreszenz-Farbstoff LysoTracker co-lokalisieren. Eine Lokalisation in Mitochondrien oder dem endoplasmatischem Retikulum konnte mit entsprechenden Fluoreszenz-Farbstoffen ausgeschlossen werden. Zusätzlich reicherten sich die überexprimierten Proteine hCAT-1.EGFP, hCAT-2B.EGFP und SLC7A14.EGFP in der lysosomalen Fraktion C aus U373MG-Zellen zusammen mit den lysosomalen Markern LAMP-1 und Cathepsin D an. Gleiches galt für den endogenen hCAT-1 in der lysosomalen Fraktion C aus EA.hy926- und U373MG-Zellen sowie für den SLC7A14 in den humanen Hautfibroblasten FCys5. Mit dem im Rahmen dieser Arbeit generierte Antikörper gegen natives SLC7A14 konnte erstmals die endogene Expression und Lokalisation von SLC7A14 in verschiedenen Zelltypen analysiert werden.rnObwohl eine Herunterregulation des hCAT-1 in EA.hy926-Endothelzellen nicht zu einer Reduktion der Versorgung der eNOS mit lysosomalem Arginin führte, ist eine Funktion von hCAT-1 im Lysosom wahrscheinlich. Sowohl die [3H]Arginin- als auch die [3H]Lysin-Aufnahme der Fraktion C aus U373MG-hCAT-1.EGFP war signifikant höher als in die Fraktion C aus EGFP-Kontrollzellen. Dies konnte ebenfalls für den hCAT-2B.EGFP gezeigt werden. Zusätzlich zeigten lysosomale Proben aus U373MG-hCAT-2B.EGFP-Zellen in der SSM-basierten Elektrophysiologie eine elektrogene Transportaktivität für Arginin. Das Protein SLC7A14.EGFP zeigte in keiner der beiden durchgeführten Transportstudien eine Aktivität. Dies war unerwartet, da die aus der Diplomarbeit stammende und im Rahmen dieser Dissertation erweiterte Charakterisierung der hCAT-2/A14_BK-Chimäre, die die „funktionelle Domäne“ des SLC7A14 im Rückgrat des hCAT-2 trug, zuvor den Verdacht erhärtet hatte, dass SLC7A14 ein lysosomal lokalisierter Transporter für KAS sein könnte. Diese Studien zeigten allerding erstmals, dass die „funktionelle Domäne“ der hCATs die pH-Abhängigkeit vermittelt und eine Rolle in der Substraterkennung spielt.rnZukünftig soll weiter versucht werden auch endogen eine Transportaktivität der hCATs für KAS im Lysosom nachzuweisen und das Substrat für das intrazellulär lokalisierte Waisen-Protein SLC7A14 zu finden. Eine mögliche Rolle könnte SLC7A14 als Transporter für Neurotransmitter spielen, da eine sehr prominente Expression im ZNS festgestellt wurde.rn

Funktionelle Analyse der onkologisch relevanten Protease Threonin-Aspartase 1

Krebs stellt eine der häufigsten Todesursachen in Europa dar. Grundlage für eine langfristige Verbesserung des Behandlungserfolgs ist ein molekulares Verständnis der Mechanismen, welche zur Krankheitsentstehung beitragen. In diesem Zusammenhang spielen Proteasen nicht nur eine wichtige Rolle, sondern stellen auch bei vielerlei Erkrankungen bereits anerkannte Zielstrukturen derzeitiger Behandlungsstrategien dar. Die Protease Threonin Aspartase 1 (Taspase1) spielt eine entscheidende Rolle bei der Aktivierung von Mixed Lineage Leukemia (MLL)-Fusionsproteinen und somit bei der Entstehung aggressiver Leukämien. Aktuelle Arbeiten unterstreichen zudem die onkologische Relevanz von Taspase1 auch für solide Tumore. Die Kenntnisse über die molekularen Mechanismen und Signalnetzwerke, welche für die (patho)biologischen Funktionen von Taspase1 verantwortlich sind, stellen sich allerdings noch immer als bruchstückhaft dar. Um diese bestehenden Wissenslücken zu schließen, sollten im Rahmen der Arbeit neue Strategien zur Inhibition von Taspase1 erarbeitet und bewertet werden. Zusätzlich sollten neue Einsichten in evolutionären Funktionsmechanismen sowie eine weitergehende Feinregulation von Taspase1 erlangt werden. Zum einen erlaubte die Etablierung und Anwendung eines zellbasierten Taspase1-Testsystem, chemische Verbindungen auf deren inhibitorische Aktivität zu testen. Überraschenderweise belegten solch zelluläre Analysen in Kombination mit in silico-Modellierungen eindeutig, dass ein in der Literatur postulierter Inhibitor in lebenden Tumorzellen keine spezifische Wirksamkeit gegenüber Taspase1 zeigte. Als mögliche Alternative wurden darüber hinaus Ansätze zur genetischen Inhibition evaluiert. Obwohl publizierte Studien Taspase1 als ααββ-Heterodimer beschreiben, konnte durch Überexpression katalytisch inaktiver Mutanten kein trans-dominant negativer Effekt und damit auch keine Inhibition des wildtypischen Enzyms beobachtet werden. Weiterführende zellbiologische und biochemische Analysen belegten erstmalig, dass Taspase1 in lebenden Zellen in der Tat hauptsächlich als Monomer und nicht als Dimer vorliegt. Die Identifizierung evolutionär konservierter bzw. divergenter Funktionsmechanismen lieferte bereits in der Vergangenheit wichtige Hinweise zur Inhibition verschiedenster krebsrelevanter Proteine. Da in Drosophila melanogaster die Existenz und funktionelle Konservierung eines Taspase1-Homologs postuliert wurde, wurde in einem weiteren Teil der vorliegenden Arbeit die evolutionäre Entwicklung der Drosophila Taspase1 (dTaspase1) untersucht. Obwohl Taspase1 als eine evolutionär stark konservierte Protease gilt, konnten wichtige Unterschiede zwischen beiden Orthologen festgestellt werden. Neben einem konservierten autokatalytischen Aktivierungsmechanismus besitzt dTaspase1 verglichen mit dem humanen Enzym eine flexiblere Substraterkennungs-sequenz, was zu einer Vergrößerung des Drosophila-spezifischen Degradoms führt. Diese Ergebnisse zeigen des Weiteren, dass zur Definition und Vorhersage des Degradoms nicht nur proteomische sondern auch zellbiologische und bioinformatische Untersuchungen geeignet und notwendig sind. Interessanterweise ist die differentielle Regulation der dTaspase1-Aktivität zudem auf eine veränderte intrazelluläre Lokalisation zurückzuführen. Das Fehlen von in Vertebraten hochkonservierten aktiven Kernimport- und nukleolären Lokalisationssignalen erklärt, weshalb dTaspase1 weniger effizient nukleäre Substrate prozessiert. Somit scheint die für die humane Taspase1 beschriebene Regulation von Lokalisation und Aktivität über eine Importin-α/NPM1-Achse erst im Laufe der Entwicklung der Vertebraten entstanden zu sein. Es konnte also ein bislang unbekanntes evolutionäres Prinzip identifiziert werden, über welches eine Protease einen Transport- bzw. Lokalisations-basierten Mechanismus zur Feinregulation ihrer Aktivität „von der Fliege zum Menschen“ nutzt. Eine weitere Möglichkeit zur dynamischen Funktionsmodulation bieten post-translationale Modifikationen (PTMs) der Proteinsequenz, zu welcher Phosphorylierung und Acetylierung zählen. Interessanterweise konnte für die humane Taspase1 über den Einsatz unabhängiger Methoden einschließlich massenspektrometrischer Analysen eine Acetylierung durch verschiedene Histon-Acetyltransferasen (HATs) nachgewiesen werden. Diese Modifikation erfolgt reversibel, wobei vor allem die Histon-Deacetylase HDAC1 durch Interaktion mit Taspase1 die Deacetylierung der Protease katalysiert. Während Taspase1 in ihrer aktiven Konformation acetyliert vorliegt, kommt es nach Deacetylierung zu einer Reduktion ihrer enzymatischen Aktivität. Somit scheint die Modulation der Taspase1-Aktivität nicht allein über intra-proteolytische Autoaktivierung, Transport- und Interaktionsmechanismen, sondern zudem durch post-translationale Modifikationen gesteuert zu werden. Zusammenfassend konnten im Rahmen dieser Arbeit entscheidende neue Einblicke in die (patho)biologische Funktion und Feinregulation der Taspase1 gewonnen werden. Diese Ergebnisse stellen nicht nur einen wichtigen Schritt in Richtung eines verbesserten Verständnis der „Taspase1-Biologie“, sondern auch zur erfolgreichen Inhibition und Bewertung der krebsrelevanten Funktion dieser Protease dar.

Functional and structural characterization of a prokaryotic peptide transporter with features similar to mammalian PEPT1

The ydgR gene of Escherichia coli encodes a protein of the proton-dependent oligopeptide transporter (POT) family. We cloned YdgR and overexpressed the His-tagged fusion protein in E. coli BL21 cells. Bacterial growth inhibition in the presence of the toxic phosphonopeptide alafosfalin established YgdR functionality. Transport was abolished in the presence of the proton ionophore carbonyl cyanide p-chlorophenylhydrazone, suggesting a proton-coupled transport mechanism. YdgR transports selectively only di- and tripeptides and structurally related peptidomimetics (such as aminocephalosporins) with a substrate recognition pattern almost identical to the mammalian peptide transporter PEPT1. The YdgR protein was purified to homogeneity from E. coli membranes. Blue native-polyacrylamide gel electrophoresis and transmission electron microscopy of detergent-solubilized YdgR suggest that it exists in monomeric form. Transmission electron microscopy revealed a crown-like structure with a diameter of approximately 8 nm and a central density. These are the first structural data obtained from a proton-dependent peptide transporter, and the YgdR protein seems an excellent model for studies on substrate and inhibitor interactions as well as on the molecular architecture of cell membrane peptide transporters.

Mechanistic aspects of NMD in human cells

Eukaryotic mRNAs with premature translation termination codons (PTCs) are recognized and degraded through a process termed nonsense-mediated mRNA decay (NMD). To get more insight into the recruitment of the central NMD factor UPF1 to target mRNAs, we mapped transcriptome-wide UPF1-binding sites by individual-nucleotide-resolution UV cross-linking and immunoprecipitation (iCLIP) in human cells and found that UPF1 preferentially associated with 3′ UTRs in translationally active cells but underwent significant redistribution toward coding regions (CDS) upon translation inhibition. This indicates that UPF1 binds RNA before translation and gets displaced from the CDS by translating ribosomes. Corroborated by RNA immunoprecipitation and by UPF1 cross-linking to long noncoding RNAs, our evidence for translation-independent UPF1-RNA interaction suggests that the triggering of NMD occurs after UPF1 binding to mRNA, presumably through activation of RNA-bound UPF1 by aberrant translation termination. Unlike in yeast, in mammalian cells NMD has been reported to be restricted to cap-binding complex (CBC)–bound mRNAs during the pioneer round of translation. However, we compared decay kinetics of two NMD reporter genes in mRNA fractions bound to either CBC or the eukaryotic initiation factor 4E (eIF4E) in human cells and show that NMD destabilizes eIF4E-bound transcripts as efficiently as those associated with CBC. These results corroborate an emerging unified model for NMD substrate recognition, according to which NMD can ensue at every aberrant translation termination event.

Mechanistic aspects of mRNA targeting for nonsense-mediated mRNA decay in human cells

The nonsense-mediated mRNA decay (NMD) pathway is best known as a translation-coupled quality control system that recognizes and degrades aberrant mRNAs with ORF-truncating premature termination codons (PTCs), but a more general role of NMD in posttranscriptional regulation of gene expression is indicated by transcriptome-wide mRNA profilings that identified a plethora of physiological mRNAs as NMD substrates. We try to decipher the mechanism of mRNA targeting to the NMD pathway in human cells. Recruitment of the conserved RNA-binding helicase UPF1 to target mRNAs has been reported to occur through interaction with release factors at terminating ribosomes, but evidence for translation-independent interaction of UPF1 with the 3’ untranslated region (UTR) of mRNAs has also been reported. We have transcriptome-wide determined the UPF1 binding sites by individual-nucleotide resolution UV crosslinking and immunoprecipitation (iCLIP) in human cells, untreated or after inhibiting translation. We detected a strongly enriched association of UPF1 with 3’ UTRs in undisturbed, translationally active cells. After translation inhibition, a significant increase in UPF1 binding to coding sequence (CDS) was observed, indicating that UPF1 binds RNA before translation and gets displaced from the CDS by translating ribosomes. This suggests that the decision to trigger NMD occurs after association of UPF1 with mRNA, presumably through activation of RNA-bound UPF1 by aberrant translation termination. In a second recent study, we re-visited the reported restriction of NMD in mammals to the ‘pioneer round of translation’, i.e. to cap-binding complex (CBC)-bound mRNAs. The limitation of mammalian NMD to early rounds of translation would indicate a – from an evolutionary perspective – unexpected mechanistic difference to NMD in yeast and plants, where PTC-containing mRNAs seem to be available to NMD at each round of translation. In contrast to previous reports, our comparison of decay kinetics of two NMD reporter genes in mRNA fractions bound to either CBC or the eukaryotic initiation factor 4E (eIF4E) in human cells revealed that NMD destabilizes eIF4E-bound transcripts as efficiently as those associated with CBC. These results corroborate an emerging unified model for NMD substrate recognition, according to which NMD can ensue at every aberrant translation termination event.

eIF4E-bound mRNPs are substrates for nonsense-mediated mRNA decay in mammalian cells

Eukaryotic mRNAs with premature translation-termination codons (PTCs) are recognized and degraded by a process referred to as nonsense-mediated mRNA decay (NMD). The evolutionary conservation of the core NMD factors UPF1, UPF2 and UPF3 would imply a similar basic mechanism of PTC recognition in all eukaryotes. However, unlike NMD in yeast, which targets PTC-containing mRNAs irrespectively of whether their 5' cap is bound by the cap-binding complex (CBC) or by the eukaryotic initiation factor 4E (eIF4E), mammalian NMD has been claimed to be restricted to CBC-bound mRNAs during the pioneer round of translation. In our recent study we compared decay kinetics of two NMD reporter systems in mRNA fractions bound to either CBC or eIF4E in human cells. Our findings reveal that NMD destabilizes eIF4E bound transcripts as efficiently as those associated with CBC. These results corroborate an emerging unified model for NMD substrate recognition, according to which NMD can ensue at every aberrant translation termination event. Additionally, our results indicate that the closed loop structure of mRNA forms only after the replacement of CBC with eIF4E at the 5' cap.

eIF4E‐bound mRNPs are substrates for nonsense‐mediated mRNA decay in mammalian cells

Eukaryotic mRNAs with premature translation-termination codons (PTCs) are recognized and degraded by a process referred to as nonsense-mediated mRNA decay (NMD). The evolutionary conservation of the core NMD factors UPF1, UPF2 and UPF3 would imply a similar basic mechanism of PTC recognition in all eukaryotes. However, unlike NMD in yeast, which targets PTC-containing mRNAs irrespectively of whether their 5' cap is bound by the cap-binding complex (CBC) or by the eukaryotic initiation factor 4E (eIF4E), mammalian NMD has been claimed to be restricted to CBC-bound mRNAs during the pioneer round of translation. In our recent study we compared decay kinetics of two NMD reporter systems in mRNA fractions bound to either CBC or eIF4E in human cells. Our findings reveal that NMD destabilizes eIF4E bound transcripts as efficiently as those associated with CBC. These results corroborate an emerging unified model for NMD substrate recognition, according to which NMD can ensue at every aberrant translation termination event. Additionally, our results indicate that the closed loop structure of mRNA forms only after the replacement of CBC with eIF4E at the 5' cap.

eIF4E-bound mRNPs are substrates for nonsense-mediated mRNA decay in mammalian cells

Eukaryotic mRNAs with premature translation-termination codons (PTCs) are recognized and degraded by a process referred to as nonsense-mediated mRNA decay (NMD). The evolutionary conservation of the core NMD factors UPF1, UPF2 and UPF3 would imply a similar basic mechanism of PTC recognition in all eukaryotes. However, unlike NMD in yeast, which targets PTC-containing mRNAs irrespectively of whether their 5' cap is bound by the cap-binding complex (CBC) or by the eukaryotic initiation factor 4E (eIF4E), mammalian NMD has been claimed to be restricted to CBC-bound mRNAs during the pioneer round of translation. In our recent study we compared decay kinetics of two NMD reporter systems in mRNA fractions bound to either CBC or eIF4E in human cells. Our findings reveal that NMD destabilizes eIF4E bound transcripts as efficiently as those associated with CBC. These results corroborate an emerging unified model for NMD substrate recognition, according to which NMD can ensue at every aberrant translation termination event. Additionally, our results indicate that the closed loop structure of mRNA forms only after the replacement of CBC with eIF4E at the 5' cap.

eIF4E‐bound mRNPs are substrates for nonsense‐mediated mRNA decay in mammalian cells

Eukaryotic mRNAs with premature translation-termination codons (PTCs) are recognized and degraded by a process referred to as nonsense-mediated mRNA decay (NMD). The evolutionary conservation of the core NMD factors UPF1, UPF2 and UPF3 would imply a similar basic mechanism of PTC recognition in all eukaryotes. However, unlike NMD in yeast, which targets PTC-containing mRNAs irrespectively of whether their 5' cap is bound by the cap-binding complex (CBC) or by the eukaryotic initiation factor 4E (eIF4E), mammalian NMD has been claimed to be restricted to CBC-bound mRNAs during the pioneer round of translation. In our recent study we compared decay kinetics of two NMD reporter systems in mRNA fractions bound to either CBC or eIF4E in human cells. Our findings reveal that NMD destabilizes eIF4E bound transcripts as efficiently as those associated with CBC. These results corroborate an emerging unified model for NMD substrate recognition, according to which NMD can ensue at every aberrant translation termination event. Additionally, our results indicate that the closed loop structure of mRNA forms only after the replacement of CBC with eIF4E at the 5' cap.

An integrated molecular biology and computational approach to CYP1A1 expression in human brain

The cytochromes P450 comprise a superfamily of heme-containing mono-oxygenases. These enzymes metabolize numerous xenobiotics, but also play a role in metabolism of endogenous compounds. The P450 1A1 enzyme generally metabolizes polycyclic aromatic hydrocarbons, and its expression can be induced by aryl hydrocarbon receptor (AhR) activation. CYP1A1 is an exception to the generality that the majority of CYPs demonstrate highest expression in liver; CYP1Al is present in numerous extrahepatic tissues, including brain. This P450 has been observed in two forms, wildtype (WT) and brain variant (BV), arising from alternatively spliced mRNA transcripts. The CYP1A1 BV mRNA presented an exon deletion and was detected in human brain but not liver tissue of the same individuals. ^ Quantitative PCR analyses were performed to determine CYP1A1 WT and BV transcript expression levels in normal, bipolar disorder or schizophrenic groups. In our samples, we show that CYP1A1 BV mRNA, when present, is found alongside the full-length form. Furthermore, we demonstrate a significant decrease in expression of CYP1A1 in patients with bipolar disorder or schizophrenia. The expression level was not influenced by post-mortem interval, tissue pH, age, tobacco use, or lifetime antipsychotic medication load. ^ There is no indication of increased brain CYP1A1 expression in normal smokers versus non-smokers in these samples. We observed slightly increased CYP1A1 expression only in bipolar and schizophrenic smokers versus non-smokers. This may be indicative of complex interactions between neuronal chemical environments and AhR-mediated CYP1A1 induction in brain. ^ Structural homology modeling demonstrated that P450 1A1 BV has several alterations to positions/orientations of substrate recognition site residues compared to the WT isoform. Automated substrate docking was employed to investigate the potential binding of neurological signaling molecules and neurotropic drugs, as well as to differentiate specificities of the two P450 1A1 isoforms. We consistently observed that the BV isoform produced energetically favorable substrate dockings in orientations not observed for the same substrate in the WT isoform. These results demonstrated that structural differences, namely an expanded substrate access channel and active site, confer greater capacity for unique compound docking positions suggesting a metabolic profile distinct from the wildtype form for these test compounds. ^

Identification of the von Hippel–Lindau tumor-suppressor protein as part of an active E3 ubiquitin ligase complex

Mutations of von Hippel–Lindau disease (VHL) tumor-suppressor gene product (pVHL) are found in patients with dominant inherited VHL syndrome and in the vast majority of sporadic clear cell renal carcinomas. The function of the pVHL protein has not been clarified. pVHL has been shown to form a complex with elongin B and elongin C (VBC) and with cullin (CUL)-2. In light of the structural analogy of VBC-CUL-2 to SKP1-CUL-1-F-box ubiquitin ligases, the ubiquitin ligase activity of VBC-CUL-2 was examined in this study. We show that VBC-CUL-2 exhibits ubiquitin ligase activity, and we identified UbcH5a, b, and c, but not CDC34, as the ubiquitin-conjugating enzymes of the VBC-CUL-2 ubiquitin ligase. The protein Rbx1/ROC1 enhances ligase activity of VBC-CUL-2 as it does in the SKP1-CUL-1-F-box protein ligase complex. We also found that pVHL associates with two proteins, p100 and p220, which migrate at a similar molecular weight as two major bands in the ubiquitination assay. Furthermore, naturally occurring pVHL missense mutations, including mutants capable of forming a complex with elongin B–elongin C-CUL-2, fail to associate with p100 and p220 and cannot exhibit the E3 ligase activity. These results suggest that pVHL might be the substrate recognition subunit of the VBC-CUL-2 E3 ligase. This is also, to our knowledge, the first example of a human tumor-suppressor protein being directly involved in the ubiquitin conjugation system which leads to the targeted degradation of substrate proteins.

Investigation of the mechanisms of DNA binding of the human G/T glycosylase using designed inhibitors

Deamination of 5-methylcytosine residues in DNA gives rise to the G/T mismatched base pair. In humans this lesion is repaired by a mismatch-specific thymine DNA glycosylase (TDG or G/T glycosylase), which catalyzes specific excision of the thymine base through N-glycosidic bond hydrolysis. Unlike other DNA glycosylases, TDG recognizes an aberrant pairing of two normal bases rather than a damaged base per se. An important structural issue is thus to understand how the enzyme specifically targets the T (or U) residue of the mismatched base pair. Our approach toward the study of substrate recognition and processing by catalytic DNA binding proteins has been to modify the substrate so as to preserve recognition of the base but to prevent its excision. Here we report that replacement of 2′-hydrogen atoms with fluorine in the substrate 2′-deoxyguridine (dU) residue abrogates glycosidic bond cleavage, thereby leading to the formation of a tight, specific glycosylase–DNA complex. Biochemical characterization of these complexes reveals that the enzyme protects an ≈20-bp stretch of the substrate from DNase I cleavage, and directly contacts a G residue on the 3′ side of the mismatched U derivative. These studies provide a mechanistic rationale for the preferential repair of deaminated CpG sites and pave the way for future high-resolution studies of TDG bound to DNA.

Genetic Separation of FK506 Susceptibility and Drug Transport in the Yeast Pdr5 ATP-binding Cassette Multidrug Resistance Transporter

Overexpression of the yeast Pdr5 ATP-binding cassette transporter leads to pleiotropic drug resistance to a variety of structurally unrelated cytotoxic compounds. To identify Pdr5 residues involved in substrate recognition and/or drug transport, we used a combination of random in vitro mutagenesis and phenotypic screening to isolate novel mutant Pdr5 transporters with altered substrate specificity. A plasmid library containing randomly mutagenized PDR5 genes was transformed into appropriate drug-sensitive yeast cells followed by phenotypic selection of Pdr5 mutants. Selected mutant Pdr5 transporters were analyzed with respect to their expression levels, subcellular localization, drug resistance profiles to cycloheximide, rhodamines, antifungal azoles, steroids, and sensitivity to the inhibitor FK506. DNA sequencing of six PDR5 mutant genes identified amino acids important for substrate recognition, drug transport, and specific inhibition of the Pdr5 transporter. Mutations were found in each nucleotide-binding domain, the transmembrane domain 10, and, most surprisingly, even in predicted extracellular hydrophilic loops. At least some point mutations identified appear to influence folding of Pdr5, suggesting that the folded structure is a major substrate specificity determinant. Surprisingly, a S1360F exchange in transmembrane domain 10 not only caused limited substrate specificity, but also abolished Pdr5 susceptibility to inhibition by the immunosuppressant FK506. This is the first report of a mutation in a yeast ATP-binding cassette transporter that allows for the functional separation of substrate transport and inhibitor susceptibility.

Phosphorylation Controls Timing of Cdc6p Destruction: A Biochemical Analysis

The replication initiation protein Cdc6p forms a tight complex with Cdc28p, specifically with forms of the kinase that are competent to promote replication initiation. We now show that potential sites of Cdc28 phosphorylation in Cdc6p are required for the regulated destruction of Cdc6p that has been shown to occur during the Saccharomyces cerevisiae cell cycle. Analysis of Cdc6p phosphorylation site mutants and of the requirement for Cdc28p in an in vitro ubiquitination system suggests that targeting of Cdc6p for degradation is more complex than previously proposed. First, phosphorylation of N-terminal sites targets Cdc6p for polyubiquitination probably, as expected, through promoting interaction with Cdc4p, an F box protein involved in substrate recognition by the Skp1-Cdc53-F-box protein (SCF) ubiquitin ligase. However, in addition, mutation of a single, C-terminal site stabilizes Cdc6p in G2 phase cells without affecting substrate recognition by SCF in vitro, demonstrating a second and novel requirement for specific phosphorylation in degradation of Cdc6p. SCF-Cdc4p– and N-terminal phosphorylation site–dependent ubiquitination appears to be mediated preferentially by Clbp/Cdc28p complexes rather than by Clnp/Cdc28ps, suggesting a way in which phosphorylation of Cdc6p might control the timing of its degradation at then end of G1 phase of the cell cycle. The stable cdc6 mutants show no apparent replication defects in wild-type strains. However, stabilization through mutation of three N-terminal phosphorylation sites or of the single C-terminal phosphorylation site leads to dominant lethality when combined with certain mutations in the anaphase-promoting complex.