Bacteriophage and antibiogram characterization of Staphylococcus aureus strains from hospital patients.

Tse, Suk-yee, Doris,

January 1900

Thesis--M. Phil., University of Hong Kong. / Typewritten.

Biochemical Investigation into the HNH Motif of HK97 gp74

Hyder, Batool

18 March 2014

Bacteriophages are viruses that infect bacteria. This thesis describes studies of gp74 from the bacteriophage HK97, which functions as an HNH endonuclease. HNH endonucleases are DNA digestion proteins characterized by two highly conserved His residues and an Asn residue. Like other HNH endonucleases, the activity of gp74 is dependent on binding of divalent metal ions to the HNH motif. Current work focused on confirming the identity of conserved HNH motif residues of gp74. We hypothesized the catalytic His residue is H43, the structural Asn residue is N73, and that H82 is involved in metal–binding. Additional residues in the ββα–fold, such as D42, may also bind the metal. Our bound metal analysis and the sequence of gp74 also suggest the presence of a Zn2+–finger motif. Mutations of D42 and H82 decrease the activity of gp74, without affecting the structure. These studies advance our understanding of the gp74 activity.

gp74

HNH endonuclease

bacteriophage

HK97 gp74

lamba-like bacteriophages

Biochemical Investigation into the HNH Motif of HK97 gp74

Hyder, Batool

18 March 2014

Bacteriophages are viruses that infect bacteria. This thesis describes studies of gp74 from the bacteriophage HK97, which functions as an HNH endonuclease. HNH endonucleases are DNA digestion proteins characterized by two highly conserved His residues and an Asn residue. Like other HNH endonucleases, the activity of gp74 is dependent on binding of divalent metal ions to the HNH motif. Current work focused on confirming the identity of conserved HNH motif residues of gp74. We hypothesized the catalytic His residue is H43, the structural Asn residue is N73, and that H82 is involved in metal–binding. Additional residues in the ββα–fold, such as D42, may also bind the metal. Our bound metal analysis and the sequence of gp74 also suggest the presence of a Zn2+–finger motif. Mutations of D42 and H82 decrease the activity of gp74, without affecting the structure. These studies advance our understanding of the gp74 activity.

gp74

HNH endonuclease

bacteriophage

HK97 gp74

lamba-like bacteriophages

Characterization of an Iron-Sulfur Binding Protein in the Tail Tip Complex of Bacteriophage Lambda

Tam, William

27 November 2013

The assembly of λ tail requires the action of 11 gene products which must interact in an organized fashion to assemble infectious tail particles. GpL is an essential protein for the formation of the tail tip complex and necessary for the assembly of λ tail. The work described here has shown that gpL and its homologues contain two domains where the C-terminal domain coordinates an oxygen-sensitive [4Fe-4S] 2+ cluster using 4 highly conserved cysteines. This is the first report of a bacteriophage morphogenetic protein to coordinate a [4Fe-4S]2+ cluster. Through two individual cysteine mutants, C184A and C228A, it was determined that these mutant proteins coordinate a [2Fe-2S]2+ cluster also using 4 cysteines; the fourth cysteine being non-conserved. λ tails assembled with cysteine mutant gpL resulted in a 1000-fold decrease in the titer of active tails and tail particles could not be detected by TEM indicating that λ tails cannot be assembled with cysteine mutant gpL. I propose that the coordination of a [4Fe-4S] cluster with the four conserved cysteines maintains a conformation in gpL that can optimally interact with other tail proteins for efficient tail assembly.

bacteriophage

lambda

iron-sulfur cluter

protein assembly

0487

0307

Characterization of an Iron-Sulfur Binding Protein in the Tail Tip Complex of Bacteriophage Lambda

Tam, William

27 November 2013

The assembly of λ tail requires the action of 11 gene products which must interact in an organized fashion to assemble infectious tail particles. GpL is an essential protein for the formation of the tail tip complex and necessary for the assembly of λ tail. The work described here has shown that gpL and its homologues contain two domains where the C-terminal domain coordinates an oxygen-sensitive [4Fe-4S] 2+ cluster using 4 highly conserved cysteines. This is the first report of a bacteriophage morphogenetic protein to coordinate a [4Fe-4S]2+ cluster. Through two individual cysteine mutants, C184A and C228A, it was determined that these mutant proteins coordinate a [2Fe-2S]2+ cluster also using 4 cysteines; the fourth cysteine being non-conserved. λ tails assembled with cysteine mutant gpL resulted in a 1000-fold decrease in the titer of active tails and tail particles could not be detected by TEM indicating that λ tails cannot be assembled with cysteine mutant gpL. I propose that the coordination of a [4Fe-4S] cluster with the four conserved cysteines maintains a conformation in gpL that can optimally interact with other tail proteins for efficient tail assembly.

bacteriophage

lambda

iron-sulfur cluter

protein assembly

0487

0307

Outer Membrane Vesicles: A New Paradigm of Bacterial Innate Immunity

Manning, Andrew

January 2013

<p>Outer membrane vesicles are an important constitutive product of all Gram-negative bacteria. Bacteria have evolved many responses to alleviate all different types of stress. The primary objective of this dissertation is to investigate the role of outer membrane vesicles (OMVs) as a method by which Gram-negative bacteria can quickly act to protect themselves against particular threats. Generally, we find that stressors whose primary effect is on the outer membrane can be protected against by OMVs. Throughout this study, a variety of different microbiological and biochemical methods are used to answer key questions in the innate ability of OMVs to protect against particular antimicrobials. Using Escherichia coli as well as Pseudomonas aeruginosa as model organisms we tested the ability of purified vesicles from each species to protect themselves and other hosts. Using bacteriophage T4, we investigated the ability of OMVs purified from E. coli to adsorb phage as well as how this interaction affected the efficiency of infection. We found that OMVs are protective against antimicrobial peptides, as well as bacteriophage. In the course of understanding this protection we also observed and characterized the cross species effects of both OMV protection as well as phage infection. Where typically a phage infects a specific species, we found that T4 associated OMVs treating a non-native host P. aeruginosa resulted in the production of a novel prophage. Upon further examination, we determined that this induction was occurring via a novel pathway that we attempted to further characterize by performing a genetic screen to identify genes important to this induction. The work within this dissertation fully supports the hypothesis of a regulated response to outer membrane acting stimuli, resulting in the induction of vesiculation and the adsorption of stressor in the extra-cellular milieu. This model of protection agrees with the idea of a bacterial innate defense system, which acts in the short term before the adaptive response can fully occur, resulting in a bridge between the untreated to the treated and resistant culture.</p> / Dissertation

Biochemistry

Microbiology

Virology

Antimicrobial Peptides

Bacteriophage

Outer Membrane Vesicles

Resistance

Removal of MS2 Bacteriophage, Cryptosporidium, Giardia and Turbidity by Pilot-Scale Multistage Slow Sand Filtration

DeLoyde, Jeffrey Leo

11 May 2007

This research aimed to address the knowledge gaps in the literature regarding the removal of waterborne pathogens (viruses and protozoa) by modified multistage slow sand filtration. In the current study, two pilot-scale multistage slow sand filtration systems were operated continuously for over two years. The pilot systems treated agricultural- and urban-impacted raw river water of variable quality with turbidity peaks over 300 NTU and seasonal cold temperatures <2??C. The first system (Pilot 1) consisted of two independent trains that included pre-ozonation, shallow-bed upflow gravel roughing filtration, and shallow-bed slow sand filtration. Pilot 1 was a pilot-scale version of an innovative, commercially available full-scale system. The second system (Pilot 2) included a full-depth upflow gravel roughing filter, a full-depth slow sand filter, and a second shallow-depth slow sand filter in series. The SSFs of both pilots were operated at high hydraulic loading rates (typically 0.4 m/h) at the upper limit of the literature recommended range (0.05 to 0.4 m/h). Both pilot systems provided excellent turbidity removal despite the high filtration rates. Effluent turbidity of all multistage SSF pilot systems were within the regulated effluent limits in Ontario for full-scale SSFs (below 1 NTU at least 95% of the time and never exceeded 3 NTU), despite raw water turbidity peaks over 100 NTU. The roughing filters contributed to approximately 60-80% of the full-train turbidity removal, compared to and 20-40% for the slow sand filters. On average, the second slow sand filter in pilot 2 provided almost no additional turbidity removal. The slow sand filter run lengths were short because of frequent high raw water turbidity, with about 50-80% of the runs in the range of 1-3 weeks. To prevent excessive SSF clogging and maintenance, filtration rates should be decreased during periods of high turbidity. Seven Cryptosporidium and Giardia challenge tests were conducted on the slow sand filters of both pilot systems at varying filtration rates (0.4 or 0.8 m/h), temperatures (2 to 25??C), and biological maturities (4 to 20 months). Removal of oocysts and cysts were good regardless of sand depth, hydraulic loading rate, and water temperature in the ranges tested. Average removals in the SSFs ranged from 2.6 to >4.4 logs for Cryptosporidium oocysts and ranged from >3.8 to >4.5 logs for Giardia cysts. This was consistent with findings in the literature, where oocyst and cyst removals of >4 logs have been reported. Cryptosporidium oocyst removals improved with increased biological maturity of the slow sand filters. At a water temperature of 2??C, average removal of oocysts and cysts were 3.9 and >4.5 logs, respectively, in a biologically mature SSF. Doubling the filtration rate from 0.4 to 0.8 m/h led to a marginal decrease in oocyst removals. Sand depths in the range tested (37-100 cm) had no major impact on oocyst and cyst removals, likely because they are removed primarily in the upper section of slow sand filter beds by straining. In general, good oocyst and cyst removals can be achieved using shallower slow sand filter bed depths and higher filtration rates than recommended in the literature. There are very few studies in the literature that quantify virus removal by slow sand filtration, especially at high filtration rates and shallow bed depths. There are no studies that report virus removal by slow sand filtration below 10??C. As such, 16 MS2 bacteriophage challenge tests were conducted at varying water temperatures (<2 to >20??C) and filtration rates (0.1 vs. 0.4 m/h) between February and June 2006 on biologically mature slow sand filters with varying bed depths (40 vs. 90 cm). Biologically mature roughing filters were also seeded with MS2. Average MS2 removals ranged from 0.2 to 2.2 logs in the SSFs and 0.1 to 0.2 logs in the RFs under all conditions tested. Virus removal by slow sand filtration was strongly dependant on hydraulic loading rate, sand depth, and water temperature. Virus removal was greater at a sand depth of 90 cm vs. 40 cm, at an HLR of 0.1 m/h vs. 0.4 m/h, and at warm (20-24??C) vs. cold (<2-10??C) water temperatures when sufficient warm water acclimation time was provided. Increased sand depth likely increased MS2 removal because of greater detention time for predation and greater contact opportunities for attachment to sand grains and biofilms. A lower HLR would also increase MS2 removal by increasing detention time, in addition to decreasing shear and promoting attachment to filter media and biofilms. Greater MS2 removal at warmer water temperatures was attributed to improved biological activity in the filters. Schmutzdecke scraping was found to have only a minor and short-term effect on MS2 removals. Virus removal can be optimized by providing deep SSF beds and operating at low filtration rates. Virus removal may be impaired in cold water, which could affect the viability of using SSF/MSF at northern climates if communities do not use disinfection or oxidation. As a stand-alone process, slow sand filtration (with or without roughing filtration) may not provide complete virus removal and should be combined with other treatment processes such as disinfection and oxidation to protect human health.

Slow sand filtration

MS2 bacteriophage

Cryptosporidium

Giardia

Biological filtration

The Role of Bacteriophage Lambda gpK in Tail Assembly and Host Cell Entry

Coburn, David

13 February 2012

The bacteriophage lambda tail protein gpK is required for tail assembly. The activity of the protein can be found at the assembling tail tip and is believed to be localized to this structure. GpK is a 27 kDa protein that has sequence identity to two families of proteins: the Mov34 family of peptidases and the NlpC/P60 family of peptidoglycan endopeptidases. Point substitutions and complementation data confirm that gpK possesses each of these domains and that they can function in trans. When the Mov34 domain is inactivated tail assembly is disrupted whereas when the NlpC/P60 domain is inactivated tails assemble but are inactive. Evidence is presented here that the C-terminal domain possesses lytic activity in isolation but not when part of the full-length protein.

bacteriophage lambda

gpK

NlpC/P60

tail assembly

0307

The Role of Bacteriophage Lambda gpK in Tail Assembly and Host Cell Entry

Coburn, David

13 February 2012

The bacteriophage lambda tail protein gpK is required for tail assembly. The activity of the protein can be found at the assembling tail tip and is believed to be localized to this structure. GpK is a 27 kDa protein that has sequence identity to two families of proteins: the Mov34 family of peptidases and the NlpC/P60 family of peptidoglycan endopeptidases. Point substitutions and complementation data confirm that gpK possesses each of these domains and that they can function in trans. When the Mov34 domain is inactivated tail assembly is disrupted whereas when the NlpC/P60 domain is inactivated tails assemble but are inactive. Evidence is presented here that the C-terminal domain possesses lytic activity in isolation but not when part of the full-length protein.

bacteriophage lambda

gpK

NlpC/P60

tail assembly

0307

Deciphering Lysis and its Regulation in Bacteriophage T4

Moussa, Samir

2012 August 1900

Like all phages, T4 requires a holin (T) to effect lysis. The lysis event depends on the temporally regulated action of T, which accumulates in the inner membrane (IM) until, at an allele-specific time, it triggers to form a large "hole" in the membrane. Hole formation then releases T4 lysozyme into the periplasm where it degrades the cell wall to elicit cell lysis. Unlike other phages, T4 is unique in exhibiting real-time regulation of lysis based on environmental conditions. Specifically, lysis can be delayed indefinitely in the lysis-inhibited state (LIN), where the normal temporal schedule for holin-triggering is over-ridden. Recently, it was shown that the imposition of LIN was correlated with the interaction of the periplasmic domains (PD) of RI and T. These studies have been extended in this dissertation using genetic, biochemical, and structural techniques to address the molecular mechanism of the RI-T LIN system. First, the PD of RI and an RI-T complex were purified, characterized biophysically, and crystallized to yield the first atomic resolution structures of either a holin or antiholin. The RI PD is mostly alpha-helical that undergoes a conformational change, as revealed by NMR spectroscopy studies, when bound to T. The PD of T is globular with alpha-helical, beta strand, and random coil secondary structures. Additionally, the holin was genetically characterized by mutagenesis techniques, yielding new information on its role in both lysis and LIN. Lysis defective mutants in all three topological domains: cytoplasmic, transmembrane, and periplasmic, were isolated. Analysis of these mutants revealed that both the cytoplasmic and periplasmic domains are important in the oligomerization of T. During LIN, the RI PD binds the PD of T, blocking a holin oligomerization interface. Finally, the signal for the imposition of lysis inhibition has been elucidated using NMR spectroscopy and other in vitro studies. These studies have shown that the RI PD binds DNA. From these studies, new models for lysis and LIN have been constructed. Lysis occurs with the accumulation and oligomerization of T via cytoplasmic and periplasmic domain interactions. LIN is imposed when the ectopically localized DNA of a superinfecting phage interacts with RI, stabilizing it in a conformation competent in inhibiting T oligomerization and leading to lysis inhibition.

bacteriophage

T4

lysis

lysis inhibition

Bax

NMR

X-ray crystallography