Bacteriophage P22 scaffolding protein functions and mechanisms in procapsid assembly /

Marion, William R.

January 2007

Thesis (M.S.)--University of Alabama at Birmingham, 2007. / Title from first page of PDF file (viewed on June 25, 2009). Includes bibliographical references (p. 52-56).

Host factors involved in viral movement through plants

Seaberg, Bonnie Lee

15 May 2009

Tomato bushy stunt virus (TBSV) is a positive-sense single-stranded RNA virus. It encodes five open reading frames (ORFs), including two nested genes, expressing movement-associated proteins. One of these proteins, P22, interacts with a host transcription factor containing a homeodomain leucine-zipper motif, known as HFi22. Similar proteins of this type traffic their RNA from cell-to-cell, suggesting the possiblity that HFi22 is involved in the cell-to-cell movement of TBSV RNA. To further characterize the nature of the interaction between P22 and HFi22 on the cellular level, cellular fractionation experiments were conducted. To investigate the functional role of HFi22 in viral movement I attempted to inactivate its expression using a virus induced gene silencing system with a Tobacco rattle virus (TRV) vector. A final objective was based on the notion that different hosts can impact the stability of viruses used to express foreign genes of biotechnological interest. To compare virus stability in different hosts, TBSV expressing the green fluorescent protein (GFP) was inoculated onto various TBSV hosts, and infected leaf tissue was then used as inoculum to be rubbed onto a local lesion host. This technique made it possible to quantify the number of fluorescent foci versus total lesions. Results obtained for the first objective indicate that P22 and HFi22 co-fractionate in nucleus and membrane-enriched samples. In addition, it was found that HFi22 is largely conserved through a wide variety of plant species but not in lettuce, which was found to be compromised for effective virus spread. Control experiments for the second objective showed that plants were successfully silenced with TRV carrying the phytoene desaturase (PDS) gene resulting in photobleaching, however attempts to silence HFi22 have not yielded conclusive results. The results obtained for the third objective indicate there is a difference in how efficiently a foreign gene insert is maintained by TBSV in different host plants. In summary, the overall results of this research showed that host factors influence the host-virus interaction but their exact contributions remain elusive.

Tomato bushy stunt virus

P22

HFi22

Host factors involved in viral movement through plants

Seaberg, Bonnie Lee

15 May 2009

Tomato bushy stunt virus (TBSV) is a positive-sense single-stranded RNA virus. It encodes five open reading frames (ORFs), including two nested genes, expressing movement-associated proteins. One of these proteins, P22, interacts with a host transcription factor containing a homeodomain leucine-zipper motif, known as HFi22. Similar proteins of this type traffic their RNA from cell-to-cell, suggesting the possiblity that HFi22 is involved in the cell-to-cell movement of TBSV RNA. To further characterize the nature of the interaction between P22 and HFi22 on the cellular level, cellular fractionation experiments were conducted. To investigate the functional role of HFi22 in viral movement I attempted to inactivate its expression using a virus induced gene silencing system with a Tobacco rattle virus (TRV) vector. A final objective was based on the notion that different hosts can impact the stability of viruses used to express foreign genes of biotechnological interest. To compare virus stability in different hosts, TBSV expressing the green fluorescent protein (GFP) was inoculated onto various TBSV hosts, and infected leaf tissue was then used as inoculum to be rubbed onto a local lesion host. This technique made it possible to quantify the number of fluorescent foci versus total lesions. Results obtained for the first objective indicate that P22 and HFi22 co-fractionate in nucleus and membrane-enriched samples. In addition, it was found that HFi22 is largely conserved through a wide variety of plant species but not in lettuce, which was found to be compromised for effective virus spread. Control experiments for the second objective showed that plants were successfully silenced with TRV carrying the phytoene desaturase (PDS) gene resulting in photobleaching, however attempts to silence HFi22 have not yielded conclusive results. The results obtained for the third objective indicate there is a difference in how efficiently a foreign gene insert is maintained by TBSV in different host plants. In summary, the overall results of this research showed that host factors influence the host-virus interaction but their exact contributions remain elusive.

Tomato bushy stunt virus

P22

HFi22

Biological Functions of Intracellular Hepatitis B e Antigen

Mitra, Bidisha

09 1900

Indiana University-Purdue University Indianapolis (IUPUI) / The function(s) of the intracellular form of HBeAg, previously reported as the preCore protein intermediate (p22) without the N-terminal signal peptide, remains elusive. Here, we propose to elucidate the translocation of p22 during its formation from endoplasmic reticulum (ER) to cytosol, how it differs from core in its inability to form a capsid and the biological functions of cytoplasmic and nuclear p22. Firstly, we have identified that a portion of p22, after the cleavage of its signal peptide in ER, is released back into the cytosol through an ERAD-independent mechanism, as neither wildtype nor dominant-negative p97 affected the ER-to-cytosol translocation of p22 or ER-Golgi secretion of HBeAg. Secondly, despite sharing the same sequence with core protein except for the extended 10 amino acid precore region at the N-terminus, we observed that p22 wildtype and C-7Q mutant are unable to form a capsid. Thirdly, we report that p22 but not the secreted HBeAg significantly reduced interferon stimulated response element (ISRE) activity and expression of interferon stimulated genes (ISGs) upon interferon-alpha (IFN- α) stimulation. Furthermore, in line with this, RNA-seq analysis of ISG induction profile from IFN-α treated patients showed that HBeAg(+) patients exhibited reduced and weak antiviral ISG upregulations compared to HBeAg(-) patients. Further, mechanistic study indicated that while p22 did not alter the total STAT1 or p-STAT1 levels in IFN-α treated cells, it blocked the nuclear translocation of p-STAT1 by interacting with karyopherin α1, indicating that the cytoplasmic p22 may impede JAK-STAT signaling to help the virus evade host innate immune response and cause resistance to IFN therapy in patients. Additionally, nuclear p22 and nuclear core were found to interact with the promoter regions (ISRE – containing) of ISGs, suggesting a new mechanism of inhibition of ISG expression upon stimulation. Finally, we found that the nuclear p22 can bind to cccDNA minichromosome and affects cccDNA maintenance and/or transcription. Thus, our results indicate that there is a novel ER sorting mechanism for the distribution of the intracellular and secretory HBeAg, and the intracellular HBeAg may contribute to HBV persistence by interfering with IFN-α elicited JAK-STAT signaling and regulating cccDNA metabolism.

cccDNA

core

HBV

IFN signaling

p22

precore

<em>sieB</em> and <em>esc</em> genes of Bacteriophage P22: A Dissertation

Ranade, Koustubh

01 June 1993

The superinfection exclusion gene (sieB) of Salmonella phage P22 was mapped using phage deletion mutants. The DNA sequence in the region was re-examined in order to find an open reading frame consistent with the deletion mapping. Several discrepancies from the previously published sequence were discovered. The revised sequence revealed a single open reading frame of 242 codons with six likely translation initiation codons. On the basis of deletion and amber mutant phenotypes the second of these six sites was inferred to be the translation initiation site of the sieB gene. The sieB gene encodes a polypeptide with 192 amino acid residues with a calculated molecular weight of 22,442, which is in reasonable agreement with that estimated from polyacrylamide gels. The transcription start-site of sieB was identified by the use of an RNAase protection assay. The sieB promoter thus identified was inactivated by a two-base substitution in its -10 hexamer. The sieB gene of coliphage λ was also identified. The promoter for λ sieB was identified by homology to that of P22 sieB. sieB aborts the lytic development of some phages. P22 itself is insensitive to the lethal effect of SieB because it harbours a determinant called esc. It was found that the sieB gene encodes two polypeptides-SieB, which is the exclusion protein, and Esc, which is a truncated version of SieB that inhibits its action. Superinfecting P22 synthesizes an antisense RNA, sas, that inhibits synthesis of SieB but allows continued synthesis of Esc, thus allowing P22 to by-pass SieB-mediated exclusion. This translational switch induced by sas RNA is essential to vegetatively developing P22; a mutation that prevents this switch causes P22 to commit SieB-mediated suicide. It was also found that P22's Esc allows it to circumvent the SieB-mediated exclusion system of bacteriophage λ.

Bacteriophage P22

Chromosome Mapping

Superinfection

Bacteria

Genetic Phenomena

Viruses

Implementation of Emerging Technologies: Treatment Capability of Peracetic Acid and Ultraviolet Irradiation

January 2017

abstract: Advanced oxidation processes (AOP’s) are water/wastewater treatment processes simultaneously providing disinfection and potential oxidation of contaminants that may cause long-term adverse health effects in humans. One AOP involves injecting peracetic acid (PAA) upstream of an ultraviolet (UV) irradiation reactor. Two studies were conducted, one in pilot-scale field conditions and another under laboratory conditions. A pilot-scale NeoTech UV reactor (rated for 375 GPM) was used in the pilot study, where a smaller version of this unit was used in the laboratory study (20 to 35 GPM). The pilot study analyzed coliform disinfection and also monitored water quality parameters including UV transmittance (UVT), pH and chlorine residual. Pilot study UV experiments indicate the unit is effectively treating flow streams (>6 logs total coliforms) twice the 95% UVT unit capacity (750 GPM or 17 mJ/cm2 UV Dose). The results were inconclusive on PAA/UV inactivation due to high data variability and field operation conditions creating low inlet concentrations.Escherichia coli (E. coli) bacteria and the enterobacteria phage P22—a surrogate for enteric viruses—were analyzed. UV inactivated >7.9 and 4 logs of E. coli and P22 respectively at a 16.8 mJ/cm2 UV dose in test water containing a significant organics concentration. When PAA doses of 0.25 and 0.5 mg/L were injected upstream of UV at approximately the same UV Dose, the average E.coli log inactivation increased to >8.9 and >9 logs respectively, but P22 inactivation decreased to 2.9 and 3.0 logs, respectively. A bench-scale study with PAA was also conducted for 5, 10 and 30 minutes of contact time, where 0.25 and 0.5 mg/L had <1 log inactivation of E. coli and P22 after 30 minutes of contact time. In addition, degradation of the chemical N-Nitrosodimethylamine (NDMA) in tap water was analyzed, where UV degraded NDMA by 48 to 97% for 4 and 0.5 GPM flowrates, respectively. Adding 0.5 mg/L PAA upstream of UV did not significantly improve NDMA degradation. The results under laboratory conditions indicate that PAA/UV have synergy in the inactivation of bacteria, but decrease virus inactivation. In addition, the pilot study demonstrates the applicability of the technology for full scale operation. / Dissertation/Thesis / Masters Thesis Civil and Environmental Engineering 2017

Environmental engineering

AOP

E. coli

NDMA

P22

Peracetic

Ultraviolet

Characterization of the Salmonella typhimuriumopdA gene, encoding oligopeptidase A: Nucleotide sequence; identity with the Escherichia coliprlC gene; and its role in bacteriophage P22 development

Conlin, Christopher Arthur

January 1992

No description available.

Bedeutung eines hydrophoben Seitenkettenstapels für Stabilität, Faltung und Struktur des P22 Tailspikeproteins / Importance of a hydrophobic side chain stack for stability, folding and structure of the P22 tailspike protein

Becker, Marion

January 2009

Das homotrimere Tailspikeadhäsin des Bakteriophagen P22 ist ein etabliertes Modellsystem, dessen Faltung, Assemblierung und Stabilität in vivo und in vitro umfassend charakterisiert ist. Das zentrale Strukturmotiv des Proteins ist eine parallele beta-Helix mit 13 Windungen, die von einer N‑terminalen Kapsidbindedomäne und einer C‑terminalen Trimerisierungsdomäne flankiert wird. Jede Windung beinhaltet drei kurze beta-Stränge, die durch turns und loops unterschiedlicher Länge verbunden sind. Durch den sich strukturell wiederholenden, spulenförmigen Aufbau formen beta-Stränge benachbarter Windungen elongierte beta-Faltblätter. Das Lumen der beta-Helix beinhaltet größtenteils hydrophobe Seitenketten, welche linear und sehr regelmäßig entlang der Längsachse gestapelt sind. Eine hoch repetitive Struktur, ausgedehnte beta-Faltblätter und die regelmäßige Anordnung von ähnlichen oder identischen Seitenketten entlang der beta-Faltblattachse sind ebenfalls typische Kennzeichen von Amyloidfibrillen, die bei Proteinfaltungskrankheiten wie Alzheimer, der Creutzfeld-Jakob-Krankheit, Chorea Huntington und Typ-II-Diabetes gebildet werden. Es wird vermutet, dass die hohe Stabilität des Tailspikeproteins und auch die der Amyloidfibrille durch Seitenkettenstapelung, einem geordneten Netzwerk von Wasserstoffbrückenbindungen und den rigiden, oligomeren Verbund bedingt ist. Um den Einfluss der Seitenkettenstapelung auf die Stabilität, Faltung und Struktur des P22 Tailspikeproteins zu untersuchen, wurden sieben Valine in einem im Lumen der beta-Helix begrabenen Seitenkettenstapel gegen das kleinere und weniger hydrophobe Alanin und das voluminösere Leucin substituiert. Der Einfluss der Mutationen wurde anhand zweier Tailspikevarianten, dem trimeren, N‑terminal verkürzten TSPdeltaN‑Konstrukt und der monomeren, isolierten beta-Helix Domäne analysiert. Generell wurde in den Experimenten deutlich, dass Mutationen zu Alanin stärkere Effekte auslösen als Mutationen zu Leucin. Die dichte und hydrophobe Packung im Kern der beta-Helix bildet somit die Basis für Stabilität und Faltung des Proteins. Anhand hoch aufgelöster Kristallstrukturen jeweils zweier Alanin‑ und Leucin‑Mutanten konnte verdeutlicht werden, dass das Strukturmotiv der parallelen beta-Helix stark formbar ist und mutationsbedingte Änderungen des Seitenkettenvolumens durch kleine und lokale Verschiebung der Haupt‑ und Seitenketten ausgeglichen werden, sodass mögliche Kavitäten gefüllt und sterische Spannung abgebaut werden können. Viele Mutanten zeigten in vivo und in vitro einen temperatursensitiven Faltungsphänotyp (temperature sensitive for folding, tsf), d.h. bei Temperaturerhöhung waren die Ausbeuten des N‑terminal verkürzten Trimers im Vergleich zum Wildtyp deutlich verringert. Weiterführende Experimente zeigten, dass der tsf‑Phänotyp durch die Beeinflussung unterschiedlicher Stadien des Reifungsprozesses oder auch durch die Verminderung der kinetischen Stabilität des nativen Trimers ausgelöst wurde. Durch Untersuchungen am vollständigen und am N‑terminal verkürzten Wildtypprotein wurde gezeigt, dass die Entfaltungsreaktion des Tailspiketrimers komplex ist. Die Verläufe der Kinetiken folgen zwar einem apparenten Zweizustandsverhalten, jedoch sind bei Darstellung der Entfaltungsäste im Chevronplot die Abhängigkeiten der Geschwindigkeitskonstanten vom Denaturierungsmittel nicht linear, sondern in unterschiedliche Richtungen gewölbt. Dieses Verhalten könnte durch ein hoch energetisches Entfaltungsintermediat, einen breiten Übergangsbereich oder parallele Entfaltungswege hervorgerufen sein. Mit Hilfe der monomeren, isolierten beta-Helix Domäne, bei der die N‑terminale Capsidbindedomäne und die C‑terminale Trimerisierungsdomäne deletiert sind und welche als unabhängige Faltungseinheit fungiert, wurde gezeigt, dass alle Mutanten im Harnstoff‑induzierten Gleichgewicht analog zum Wildtypprotein einem Zweizustandsverhalten mit vergleichbaren Kooperativitäten folgen. Die konformationellen Stabilitäten von in der beta-Helix zentral gelegenen Alanin‑ und Leucin‑Mutanten sind stark vermindert, während Mutationen in äußeren Bereichen der Domäne keinen Einfluss auf die Stabilität der beta-Helix haben. Bei Verlängerung der Inkubationszeiten der Gleichgewichtsexperimente konnte die langsame Bildung von Aggregaten im Übergangsbereich der destabilisierten Mutanten detektiert werden. Die in der Arbeit erlangten Erkenntnisse lassen vermuten, dass die isolierte beta-Helix einem für die Reifung des Tailspikeproteins entscheidenden thermolabilen Faltungsintermediat auf Monomerebene sehr ähnlich ist. Im Intermediat ist ein zentraler Kern, der die Windungen 4 bis 7 und die „Rückenflosse“ beinhaltet, stabilitätsbestimmend. Dieser Kern könnte als Faltungsnukleus dienen, an den sich sequenziell weitere Helixwindungen anlagern und im Zuge der „Monomerreifung“ kompaktieren. / The homotrimeric tailspike adhesin of bacteriophage P22 is a widely used model system for studying different aspects of multi-domain protein folding, assembly and stability, both in vivo and in vitro. The central domain of the tailspike protein is a 13-turn right-handed parallel beta-helix, flanked by an N-terminal capsid-binding domain and a C-terminal trimerization domain. In the beta-helix motif the polypeptide backbone winds up to form a right-handed helix, with each coil consisting of three short beta-strands connected by turns and loops of varying lengths. Due to this repetitive and solenoidal structure, beta-strands of adjacent coils participate in building up three elongated beta-sheets. The internal lumen of the beta-helix is tightly packed and contains mostly hydrophobic side-chains, which are stacked along the helical axis in a linear and very regular manner. A highly repetitive structure, elongated beta-sheets and stacking of similar or identical side chains along the beta-sheet axis are also typical characteristics of amyloid fibrils, which are associated with protein folding diseases such as Alzheimer’s disease, Creutzfeldt-Jacob disease, Huntington’s disease and type II diabetes. It is assumed that the high stability of both, the tailspike protein and amyloid fibrils, is determined by side chain stacking, a well‑ordered network of H-bonds and the rigid, oligomeric state. To systematically investigate the influence of side chain stacking for stability, folding and structure of the P22 tailspike protein, a hydrophobic stack located in the lumen of the beta-helix domain was subjected to site-directed mutagenesis. Each of seven valine residues, distributed over the whole length of the beta-helix domain, was substituted by the smaller and less hydrophobic alanine and the bulkier leucine. The influence of these substitutions was investigated with the help of two tailspike protein constructs, namely the N-terminally shortened TSPdeltaN construct and the isolated, monomeric BHX construct. In general, almost all experiments showed that alanine mutations cause a stronger effect than leucine mutations, which demonstrates that the tight and hydrophobic packing in the lumen of the beta-helix domain is the basis for stability and folding of the tailspike protein. High-resolution crystal structures of two alanine and two leucine mutants revealed that the parallel beta-helix motif shows considerable plasticity. Small and local adjustments of side chains and the polypeptide backbone compensate for changes induced by the mutations, herewith potential cavities are filled and steric strain is released. Compared to the wild type, many mutations lead to a temperature sensitive for folding (tsf) phenotype in vivo and in vitro, i.e. mutations reduce folding yields of TSPdeltaN at high temperatures, but had little effect at low temperatures. Our experiments have elucidated that the tsf phenotype was caused either by an impact on different stages of the maturation process or by a reduction of the kinetic stability of the native trimer. Using TSPdeltaN and the complete wild type protein, it was shown that the tailspike trimer unfolds in a complex manner. Although unfolding kinetics exhibit a two-state behaviour, analysis of the apparent rate constants of unfolding in a Chevron plot revealed their non-linear denaturant-dependence. Typically, the natural logarithm of the apparent rate constants depend linearly on the denaturant concentration. However, in case of TSPdeltaN and the complete wild type protein, unfolding branches of the Chevron plot are curved. Such a behaviour could arise from a high energy intermediate on the unfolding pathway, a broad activation barrier or parallel unfolding pathways. The monomeric BHX construct lacks both the N-terminal and C-terminal domain. It folds into a conformation very similar to that of the -helix domain in the tailspike trimer and acts as an independent folding unit. Unfolding and refolding equilibrium transitions of mutant and wild type BHX constructs are reversible and follow a two-state behaviour with comparable cooperativities. However, conformational stabilities of alanine and leucine mutations located in the central part of the beta-helix domain are highly reduced, whereas mutations at the ends of the domain show a wild type-like stability. Furthermore, these destabilizing mutations tend to form aggregates around the transition midpoint when equilibrium experiments were incubated for longer time periods. Taken together, the results suggest that the structure of the isolated beta-helix seems to be similar to an essential, monomeric intermediate during tailspike folding. In this intermediate, a central core including coils 4 to 7 and the dorsal fin determines the stability of the whole folding unit. This core may act as a nucleus on which beta-helix coils can associate in a sequential manner and compact during maturation of the monomer.

P22 Tailspikeprotein

Seitenkettenstapel

beta-Solenoidproteine

Proteinfaltung

thermodynamische Stabilität

P22 tailspike protein

side chain stacking

beta-solenoid proteins

protein folding

thermodynamic stability

Life sciences

Use of surfaces functionalized with phage tailspike proteins to capture and detect bacteria in biosensors and bioassays

Dutt, Sarang

11 1900

The food safety and human diagnostics markets are in need of faster working, reliable, sensitive, specific, low cost bioassays and biosensors for bacterial detection. This thesis reports the use of P22 bacteriophage tailspike proteins (TSP) immobilized on silanized silicon surfaces, roughened at a nano-scale, for specific capture and detection of Salmonella. Towards developing TSP biosensors, TSP immobilization characteristics were studied, and methods to improve bacterial capture were explored. Atomic force microscopy was used to count TSP immobilized on gold thin-films. Surface density counts are dependent on the immobilization scheme used. TSP immobilized on flat silicon (Si), silanized with 3-aminopropyltriethoxysilane and activated with glutaraldehyde, showed half the bacterial capture of gold thin-films. To improve bacterial capture, roughened mountain-shaped ridge-covered silicon (MSRCS) surfaces were coated with TSP and tested. Measurements of their bacterial surface density show that such MSRCS surfaces can produce bacterial capture close to or better than TSP-coated gold thin-films. / Biomedical Engineering

PROPERTIES OF THE TOMBUSVIRUS MOVEMENT PROTEIN AND RNAi SUPPRESSOR THAT INFLUENCE PATHOGENESIS

Hsieh, Yi-Cheng

16 January 2010

Tomato bushy stunt virus (TBSV) provides a good model system to investigate molecular virus-host interactions in plants. P22 and P19 proteins encoded by TBSV contribute to multiple invasion-associated functions. Green fluorescence-mediated visualization of TBSV invasion in this study suggests that virus exit from inoculated epidermal cells is a crucial event. Close examination of one P22 mutant showed that it had lost the capacity to move between epidermis and mesophyll which was possibly due to an altered subcellular localization. P19 is a potent suppressor of RNA interference (RNAi) in various systems by forming dimers that bind 21-nucleotide (nt) duplex siRNAs (short interfering RNAs), to affect the programming of the RNA-induced silencing complex (RISC). P19 is attractive for biotechnological and research purposes to prevent RNAi of certain value-added genes in plants. To obtain a good plant-based expression platform, a suppression-active mutant P19 was expressed in transgenic N. benthamiana lines. This is the first example of P19 accumulating to detectable levels in a transgenic plant and initial results suggest it is actively suppressing RNAi. Furthermore, to investigate the correlation between siRNA binding of P19 and its various biological roles, predicted siRNA-interacting sites of TBSV P19 were modified, and the corresponding TBSV mutants were used to inoculate plants. Substitutions on siRNA-contact sites on the central domain of P19 resulted in more severe symptoms in N. benthamiana compared to those affecting peripheral regions. All tested combinations of siRNA-binding mutations were associated with reduced accumulation of total TBSV-derived siRNAs, and loss of siRNA sequestration by P19. Additionally, some modifications were found to cause RNAi-mediated disappearance of viral and host materials in N. benthamiana but not in spinach. In conclusion, exit out of epidermal cells is a key host range determinant for TBSV and particular amino acids on P22 may influence this by regulating the proper subcellular localization. Mutant P19 transgenic plants were successfully established with minor physiological effects to be applied as a platform to study RNAi and to over-express proteins. Finally, a compromised P19-siRNA binding impacts symptom development, systemic invasion, integrity of virus plus host RNA and proteins, and that all in a hostdependent manner.

TBSV

P19

RNAi

suppressor

siRNA

pathogenesis

P22

movement protein

cell-to-cell movement