Characterisation of proteins involved in CRISPR-mediated antiviral defence in Sulfolobus solfataricus

Kerou, Melina L.

January 2012

One of the most surprising realisations to emerge from metagenomics studies in the early ‘00s was that the population of viruses and phages in nature is about 10 times larger than the population of prokaryotic organisms. Thus, bacteria and archaea are under constant pressure to develop resistance methods against a population of viruses with extremely high turnover and evolution rates, in what has been described as an evolutionary “arms race”. A novel, adaptive and heritable immune system encoded by prokaryotic genomes is the CRISPR/Cas system. Arrays of clustered regularly interspersed short palindromic repeats (CRISPR) are able to incorporate viral or plasmid sequences which are then used to inactivate the corresponding invader element via an RNA interference mechanism. A number of CRISPR-associated (Cas) protein families are responsible for the maintenance, expansion and function of the CRISPR loci. This system can be classified in a number of types and subtypes that differ widely in their gene composition and mode of action. This thesis describes the biochemical characteristics of CRISPR-mediated defense in the crenarchaeon Sulfolobus solfataricus. The process of CRISPR loci transcription and their subsequent maturation into small guide crRNA units by the processing endonuclease of the system (Cas6) is investigated. After this step, different pathways and effector proteins are involved in the recognition and silencing of DNA or RNA exogenous nucleic acids. This thesis reports the identification and purification of a native multiprotein complex from S. solfataricus P2, the Cmr complex, a homologue of which has been found to recognise and cleave RNA targets in P. furiosus. The recognition and silencing of DNA targets in E. coli has been shown to involve a multiprotein complex termed CASCADE as well as Cas3, a putative helicase-HD nuclease. S. solfataricus encodes orthologues for the core proteins of this complex, and the formation and function of an archaeal CASCADE is investigated in this thesis.

615.7

Investigation into the twin-arginine translocation pathway of halophilic and thermophilic archaea

Kwan, Daniel

January 2009

The Twin arginine translocation pathway translocates fully folded proteins across cellular membranes and is only utilised by proteins that fold before translocation. It is a unique process that is found in many bacteria, archaea and also in plant chloroplasts. Investigation of the bacterial and thylakoidal systems has revealed much of the substrates and the components involved in their translocation. Unfortunately, there are still many unanswered questions such as how substrates are directed to the membrane and the actual mechanism of translocation. This thesis specifically investigates the Tat pathway of halophilic and thermophilic archaea. To date, there has been a lack of research into the archaeal Tat pathway and it is possible that there are unique adaptations because of the extreme environments that these organisms inhabit. Chapter 3 specifically investigates the thermophiles Sulfolobus solfataricus and Sulfolobus tokodaii and attempts to purify their Tat complexes. By doing so it was hoped to learn more about the Tat components and their interactions. Further experiments were also performed to determine if the two S. solfataricus Tat operons provide specificity to the Tat substrates that translocate. Four separate areas of the Tat pathway of halophilic archaea (haloarchaea) were investigated in Chapters 4-7. Firstly, site-directed mutagenesis was used to analyse the signal peptides of haloarchaeal Tat substrates in more detail. Consequently, the resulting data led to the use of bioinformatics to analyse the Haloarchaeal signal peptide. The bioenergetics of the Tat system was then determined by analysing the effect of a variety of ionophores on translocation of the Tat substrates AmyH and SptA. Finally, a series of folding and stability assays were used to increase our understanding of AmyH, which could provide further information on why this protein, like many other haloarchaeal proteins, requires the Tat pathway for translocation.

571.29

The characterization of lytic viruses infecting the hyperthermophilic Sulfolobus islandicus isolated from Yellowstone National Park

Fackler, Joseph R.

15 October 2015

No description available.

Virology

Sulfolobus

Rudivirus

SIRV

Archaea

Virus resistance

Hyperthermophilic

Genetic stability in the hyperthermophilic archaeon Sulfolobus acidocaldarius

Cong, Xinyu

15 October 2015

No description available.

Microbiology

archaea

sulfolobus

B-family polymeraes

TLS

TAM

genetic stability

Virus d'archées : interaction avec un hôte hyperthermophile, isolement d'un virus d'habitat géothermique, motifs courts exceptionnels dans les génomes / Archaeal viruses : interaction with a hyperthermophilic host, isolation of a virus from a geothermal environment, short exceptional motifs in genomes

Bize, Ariane

03 April 2009

Les microorganismes du domaine du vivant Archaea sont très divers sur le plan biologique et sont présents dans de nombreux types d'écosystèmes. Ils sont majoritaires dans les environnements dits extrêmes. Parmi les virus d'archées, ceux infectant les espèces d'un phylum majeur des archées, Crenarchaeota, constitué d'hyperthermophiles, forment un groupe exceptionnel. En effet, leurs morphotypes sont uniques, variés, et complexes. Le contenu de leur génome est également unique. Enfin, la plupart de ces virus se maintiennent dans la cellule hôte en état porteur, une relation chronique qui permet un équilibre entre production de virions et division cellulaire. J'ai d'abord démontré que le virus de crenarchée Sulfolobus islandicus rod-shaped virus 2 est un virus virulent, et non chronique comme il avait été suggéré. Un mécanisme de lyse unique a été découvert. La paroi cellulaire est modifiée en plusieurs points, avec l'apparition de structures pyramidales saillantes. Celles-ci s'ouvrent en fin de cycle infectieux, permettant aux virions, assemblés auparavant dans le cytoplasme, de quitter la cellule. Puis j'ai travaillé sur des échantillons de sources géothermiques de la péninsule de Kamchatka (Russie) et contribué à l'isolement et la caractérisation d'un virus de morphotype filamenteux. Des protéines structurales supplémentaires ont ainsi été identifiées. Enfin, des mots courts exceptionnels ont été identifiés dans un grand nombre de génomes d'archées et de leurs éléments extra-chromosomiques. Ce sont potentiellement des motifs fonctionnels non-codants, impliqués dans des mécanismes biologiques importants. Typiquement, les motifs palindromiques sont évités dans les génomes / The microorganisms from the Archaea domain are very diverse at the biological level and they are present in many types of ecosystems. They are dominant in the so-called extreme environments. Among their viruses, those infecting species of the Crenarchaeota phylum, a major archaeal phylum comprising hyperthermophiles, form an exceptional group. Indeed, their morphotypes are unique, diverse, and complex. Their genome content is also unique. Finally, most of these viruses persist in the host cell in a carrier state, a chronic relationship allowing an equilibrium between virion production and cell division. I first proved that Sulfolobus islandicus rod-shaped virus 2 is a virulent virus, and not chronic, as had previously been suggested. A unique lysis mechanism was discovered. The cell wall is modified in several locations, with the appearance of pyramidal prominent structures. Those burst open at the end of the infection cycle, allowing the virions, previously assembled in the cytoplasm, to leave the cell. Then, I worked on environmental samples from geothermal springs of the Kamchatka peninsula (Russia) and contributed to the isolation and characterization of a virus of filamentous morphotype. Additional structural proteins were in particular identified. Finally, short exceptional words were identified in a great number of genomes from archaea and their extra-chromosomal elements. These are potentially functional non-coding motifs involved in important biological mechanisms. Typically, palindromic motifs are avoided in the genomes

Archaea

Virus

Sulfolobus

Cycle infectieux

Interaction hôte-virus

Motifs exceptionnels

Archaea

Virus

Sulfolobus

Infection cycle

Host-virus interaction

Exceptional motifs

U(VI) bioaccumulation by Paenibacillus sp. JG-TB8 and Sulfolobus acidocaldarius

Reitz, Thomas

01 February 2012

In this thesis, the interactions of U(VI) with one representative each of the domains Bacteria (Paenibacillus sp. JG TB8) and Archaea (Sulfolobus acidocaldarius) are compared. We demonstrate that at highly acidic conditions (pH ≤ 3), U(VI) is bound to cells of the both strains exclusively via organic phosphate groups. In contrast to this, the U(VI) complexation modes differ between the studied strains at moderate acidic conditions. These differences are assigned to the different cell wall structures of both strains as well as to their different physiological characteristics. We also demonstrate that the aeration conditions can strongly influence the uranium accumulation of facultative anaerobic microorganisms at moderate acidic pH conditions. This finding could clearly be assigned to the dependency of the intrinsic phosphatase activity on the aeration conditions. The second part of this thesis deals with the outermost surface layer (SlaA-layer) of S. acidocaldarius. It was shown that this surface protein is not involved in the U(VI) complexation at highly acidic conditions, covering the physiological pH optimum of S. acidocaldarius. Hence the SlaA layer does not provide a protective function against U(VI) to the cells of this acidophilic archaeon. However, we demonstrated that purified SlaA-layer ghosts (i.e. empty cell sacculi) efficiently interact with gold ions and are a good macromolecular template for the formation of magnetic gold nanoparticles. / In dieser Doktorarbeit werden die Wechselwirkungen von U(VI) mit je einem Vertreter der Bakterien (Paenibacillus sp. JG TB8) und Archeen (Sulfolobus acidocaldarius) verglichen. Wir konnten zeigen, dass U(VI) im sehr sauren Milieu (pH ≤ 3) ausschließlich durch organische Phosphatgruppen an die Zellen beider Stämme gebunden ist. Im Gegensatz dazu unterscheiden sich die Mechanismen der U(VI)-Komplexierung beider untersuchter Stämme bei mäßig sauren Bedingungen voneinander. Diese Unterschiede basieren auf den unterschiedlichen Zellwandstrukturen und physiologischen Eigenschaften beider Stämme. Wir konnten außerdem zeigen, dass die atmosphärischen Bedingungen die Urankomplexierung durch fakultativ anaerobe Mikroorganismen bei mäßig sauren Bedingungen stark beeinflussen kann. Dieses Ergebnis konnte eindeutig auf die von den atmosphärischen Bedingungen-abhängige, enzymatische Aktivität der zelleigenen Phosphatase zurückgeführt werden. Der zweite Teil dieser Arbeit beschäftigt sich mit der äußeren Oberflächenschicht (SlaA-layer) von S. acidocaldarius. Es konnte gezeigt werden, dass dieses Oberflächenprotein nicht an der U(VI)-Komplexierung bei stark sauren pH, welcher dem physiologischen pH Optimum von S. acidocaldarius entspricht, beteiligt ist. Damit stellt der SlaA-layer keinen Schutz gegen Uran für die Zellen dieses azidothermophilen Archaeons dar. Allerdings konnten wir zeigen, dass isolierte „SlaA-layer ghosts“ (d.h. leere Zellhüllen) mit Goldionen interagieren und sich daher als makromolekulares Template für die Herstellung magnetischer Gold Nanopartikel eignen.

Uran

Sulfolobus

Wechselwirkungen

Mikroorganismen

S-layer

Paenibacillus

Biomineralisierung

Biosorption

Gold Nanocluster

Uranium

Sulfolobus

Interactions

Microorganisms

S-layer

Paenibacillus

Biomineralization

Biosorption

Gold nanocluster

ddc:570

Uran

Sulfolobus acidocaldarius

Komplexbildungsreaktion

Mikroorganismus

U(VI) bioaccumulation by Paenibacillus sp. JG-TB8 and Sulfolobus acidocaldarius: U(VI) bioaccumulation by Paenibacillus sp. JG-TB8 and Sulfolobus acidocaldarius: Au(0) nanoclusters formation on the S-layer of S. acidocaldarius

Reitz, Thomas

13 December 2011

In this thesis, the interactions of U(VI) with one representative each of the domains Bacteria (Paenibacillus sp. JG TB8) and Archaea (Sulfolobus acidocaldarius) are compared. We demonstrate that at highly acidic conditions (pH ≤ 3), U(VI) is bound to cells of the both strains exclusively via organic phosphate groups. In contrast to this, the U(VI) complexation modes differ between the studied strains at moderate acidic conditions. These differences are assigned to the different cell wall structures of both strains as well as to their different physiological characteristics. We also demonstrate that the aeration conditions can strongly influence the uranium accumulation of facultative anaerobic microorganisms at moderate acidic pH conditions. This finding could clearly be assigned to the dependency of the intrinsic phosphatase activity on the aeration conditions. The second part of this thesis deals with the outermost surface layer (SlaA-layer) of S. acidocaldarius. It was shown that this surface protein is not involved in the U(VI) complexation at highly acidic conditions, covering the physiological pH optimum of S. acidocaldarius. Hence the SlaA layer does not provide a protective function against U(VI) to the cells of this acidophilic archaeon. However, we demonstrated that purified SlaA-layer ghosts (i.e. empty cell sacculi) efficiently interact with gold ions and are a good macromolecular template for the formation of magnetic gold nanoparticles. / In dieser Doktorarbeit werden die Wechselwirkungen von U(VI) mit je einem Vertreter der Bakterien (Paenibacillus sp. JG TB8) und Archeen (Sulfolobus acidocaldarius) verglichen. Wir konnten zeigen, dass U(VI) im sehr sauren Milieu (pH ≤ 3) ausschließlich durch organische Phosphatgruppen an die Zellen beider Stämme gebunden ist. Im Gegensatz dazu unterscheiden sich die Mechanismen der U(VI)-Komplexierung beider untersuchter Stämme bei mäßig sauren Bedingungen voneinander. Diese Unterschiede basieren auf den unterschiedlichen Zellwandstrukturen und physiologischen Eigenschaften beider Stämme. Wir konnten außerdem zeigen, dass die atmosphärischen Bedingungen die Urankomplexierung durch fakultativ anaerobe Mikroorganismen bei mäßig sauren Bedingungen stark beeinflussen kann. Dieses Ergebnis konnte eindeutig auf die von den atmosphärischen Bedingungen-abhängige, enzymatische Aktivität der zelleigenen Phosphatase zurückgeführt werden. Der zweite Teil dieser Arbeit beschäftigt sich mit der äußeren Oberflächenschicht (SlaA-layer) von S. acidocaldarius. Es konnte gezeigt werden, dass dieses Oberflächenprotein nicht an der U(VI)-Komplexierung bei stark sauren pH, welcher dem physiologischen pH Optimum von S. acidocaldarius entspricht, beteiligt ist. Damit stellt der SlaA-layer keinen Schutz gegen Uran für die Zellen dieses azidothermophilen Archaeons dar. Allerdings konnten wir zeigen, dass isolierte „SlaA-layer ghosts“ (d.h. leere Zellhüllen) mit Goldionen interagieren und sich daher als makromolekulares Template für die Herstellung magnetischer Gold Nanopartikel eignen.

info:eu-repo/classification/ddc/570

ddc:570

Characterisation of Sulfolobus solfataricus Ard1, a promiscuous N-acetyltransferase

Mackay, Dale Tara

January 2008

Compaction of DNA into chromatin is an important feature of every living cell. This compaction phenomenon is brought about and maintained by a variety of DNA binding proteins, which have evolved to suit the specific needs of the different cell types spanning the three kingdoms of life; the eukaryotes, prokaryotes and archaea. Sulfolobus solfataricus, a member of the crenarchaeal subdivision of the archaea, has two prominent DNA binding proteins known as Alba (1&2) and Sso7d. Alba1 is acetylated in vivo at two positions and this modification lowers its’ affinity for binding DNA. Acetylation levels impact many cellular processes and in higher organisms play a critical role in the development of many cancers and other diseases. This thesis documents the finding and characterisation of the N-terminal acetyltransferase (ssArd1) of SsoAlba1, based on its’ sequence homology to the catalytic subunits Ard1, Nat3 and Mak3 belonging to the larger eukaryal Nat complexes NatA, NatB and NatC, respectively. Mutagenesis studies revealed that ssArd1 preferentially acetylates N-termini bearing a serine or alanine residue at position 1 (after methionine cleavage). It is also capable of acetylating other proteins with very different physical structures. These findings allow classification of ssArd1 as a promiscuous acetyltransferase belonging to the Gcn5-N-acetyltransferase (GNAT) superfamily. The active site of the enzyme was examined through mutagenesis studies, revealing that the mechanism of acetylation is likely to proceed through a direct acetyl transfer involving a tetrahedral intermediate. Structural studies provided some insight into the molecular structure of ssArd1.

579

Virus d'archées : interaction avec un hôte hyperthermophile, isolement d'un virus d'habitat géothermique, motifs courts exceptionnels dans les génomes

D'Avezac De Castera, Ariane

03 April 2009

Les microorganismes du domaine du vivant Archaea sont très divers sur le plan biologique et sont présents dans de nombreux types d'écosystèmes. Ils sont majoritaires dans les environnements dits extrêmes. Parmi les virus d'archées, ceux infectant les espèces d'un phylum majeur des archées, Crenarchaeota, constitué d'hyperthermophiles, forment un groupe exceptionnel. En effet, leurs morphotypes sont uniques, variés, et complexes. Le contenu de leur génome est également unique. Enfin, la plupart de ces virus se maintiennent dans la cellule hôte en état porteur, une relation chronique qui permet un équilibre entre production de virions et division cellulaire. J'ai d'abord démontré que le virus de crenarchée Sulfolobus islandicus rod-shaped virus 2 est un virus virulent, et non chronique comme il avait été suggéré. Un mécanisme de lyse unique a été découvert. La paroi cellulaire est modifiée en plusieurs points, avec l'apparition de structures pyramidales saillantes. Celles-ci s'ouvrent en fin de cycle infectieux, permettant aux virions, assemblés auparavant dans le cytoplasme, de quitter la cellule. Puis j'ai travaillé sur des échantillons de sources géothermiques de la péninsule de Kamchatka (Russie) et contribué à l'isolement et la caractérisation d'un virus de morphotype filamenteux. Des protéines structurales supplémentaires ont ainsi été identifiées. Enfin, des mots courts exceptionnels ont été identifiés dans un grand nombre de génomes d'archées et de leurs éléments extra-chromosomiques. Ce sont potentiellement des motifs fonctionnels non-codants, impliqués dans des mécanismes biologiques importants. Typiquement, les motifs palindromiques sont évités dans les génomes

[SDV] Life Sciences

Archaea

Virus

Sulfolobus

Cycle infectieux

Interaction hôte-virus

Motifs exceptionnels

Continuous growth and heat shock of thermoacidophilic Sulfolobus in a triple-stage chemostat for overexpression and isolation of chaperonin

Seipel, Kurtz

01 May 2012

No description available.

Chaperonin

Chemostat Continuous Culture

Heat Shock

Protein

Sulfolobus

Thermoacidophile

Chemical Engineering