http://hdl.handle.net/10023/177 2013-05-24T08:36:49Z 2013-05-24T08:36:49Z Mazel-Sanchez, Beryl http://hdl.handle.net/10023/3230 2012-10-25T15:27:47Z 2012-11-30T00:00:00Z

Abstract: Bunyamwera orthobunyavirus (BUNV) is the prototype for the family Bunyaviridae. BUNV has a tripartite RNA genome of negative polarity composed of the large(L),medium (M)and small(S)segments. Each segment contains an open reading frame (ORF) flanked by untranslated regions (UTRs). The eleven terminal nucleotides are conserved between the three segments while the internal regions are unique. The UTRs play an important role in the virus life cycle by promoting transcription, replication and encapsidation of the viral genome.The work presented in this thesis explores UTRs plasticity and examines ways to engineere attenuated viruses by modifying only their UTRs. Using reverse genetics, mainly two ways of attenuation were explored: rescue of viruses either carrying deletions within their 3’ and/or 5’ UTRs in all three segments, or of viruses carrying one segment bearing heterologous UTRs. Both approaches resulted in virus attenuation in tissue culture, with viruses producing smaller plaques or even no plaques, and growing to lower titres than wild-type BUNV. Through serial passage, viruses were shown to regain some level of fitness while the mutations introduced in the UTRs proved to be stable. Thus, to investigate the mechanism behind fitness recovery, the nucleotide sequence of the entire genome of viruses with deletions in their UTRs was determined. Amino acid changes were observed in the viral polymerase (L protein) of most mutant viruses and the vast majority of the amino acid changes occured in the C-terminal region. The function of this domain is unclear to date, however data obtained using a mini-replicon assay suggest that the C-terminal domain of the L protein might be involved in UTR recognition. Full genome sequencing also allowed the identification of an amino acid mutation within the polymerase that resulted in a temperature sensitive phenotype when introduced in an otherwise wild-type BUNV. Thus, it was shown that mutations introduced within the UTR regions of the genome were stable through serial passage and resulted in attenuation. Such a strategy could be used in combination with mutations of the ORF to design live-attenuated vaccines against serious pathogens within the family Bunyaviridae.

2012-11-30T00:00:00Z Mazel-Sanchez, Beryl Bunyamwera orthobunyavirus (BUNV) is the prototype for the family Bunyaviridae. BUNV has a tripartite RNA genome of negative polarity composed of the large(L),medium (M)and small(S)segments. Each segment contains an open reading frame (ORF) flanked by untranslated regions (UTRs). The eleven terminal nucleotides are conserved between the three segments while the internal regions are unique. The UTRs play an important role in the virus life cycle by promoting transcription, replication and encapsidation of the viral genome.The work presented in this thesis explores UTRs plasticity and examines ways to engineere attenuated viruses by modifying only their UTRs. Using reverse genetics, mainly two ways of attenuation were explored: rescue of viruses either carrying deletions within their 3’ and/or 5’ UTRs in all three segments, or of viruses carrying one segment bearing heterologous UTRs. Both approaches resulted in virus attenuation in tissue culture, with viruses producing smaller plaques or even no plaques, and growing to lower titres than wild-type BUNV. Through serial passage, viruses were shown to regain some level of fitness while the mutations introduced in the UTRs proved to be stable. Thus, to investigate the mechanism behind fitness recovery, the nucleotide sequence of the entire genome of viruses with deletions in their UTRs was determined. Amino acid changes were observed in the viral polymerase (L protein) of most mutant viruses and the vast majority of the amino acid changes occured in the C-terminal region. The function of this domain is unclear to date, however data obtained using a mini-replicon assay suggest that the C-terminal domain of the L protein might be involved in UTR recognition. Full genome sequencing also allowed the identification of an amino acid mutation within the polymerase that resulted in a temperature sensitive phenotype when introduced in an otherwise wild-type BUNV. Thus, it was shown that mutations introduced within the UTR regions of the genome were stable through serial passage and resulted in attenuation. Such a strategy could be used in combination with mutations of the ORF to design live-attenuated vaccines against serious pathogens within the family Bunyaviridae. Szemiel, Agnieszka M. http://hdl.handle.net/10023/2570 2013-05-03T13:40:18Z 2011-01-01T00:00:00Z

Abstract: The Bunyaviridae family is one of the largest among RNA viruses, comprising more than 350 serologically distinct viruses. The family is classified into five genera, Orthobunyavirus, Hantavirus, Nairovirus, Phlebovirus, and Tospovirus. Orthobunyaviruses, nairoviruses and phleboviruses are maintained in nature by a propagative cycle involving blood-feeding arthropods and susceptible vertebrate hosts. Like most arthropod-borne viruses, bunyavirus replication causes little damage to the vector, whereas infection of the mammalian host may lead to death. This situation is mimicked in the laboratory: in cultured mosquito cells no cytopathology is observed and a persistent infection is established, whereas in cultured mammalian cells orthobunyavirus infection is lytic and leads to cell death. Bunyaviruses encode four common structural proteins: an RNA-dependent RNA polymerase, two glycoproteins (Gc and Gn), and a nucleoprotein N. Some viruses also code for nonstructural proteins called NSm and NSs. The NSs protein of the prototype bunyavirus, Bunyamwera virus, seems to be one of the factors responsible for the different outcomes of infection in mammalian and mosquito cell lines. However, only limited information is available on the growth of bunyaviruses in cultured mosquito cell lines other than Aedes albopictus C6/36 cells. Here, I compared the replication of Bunyamwera virus in two additional Aedes albopictus cell clones, C7-10 and U4.4, and two Aedes aegypti cell clones, Ae and A20, and investigated the impact of virus replication on cell function. In addition, whereas the vertebrate innate immune response to arbovirus infection is well studied, relatively little is known about mosquitoes’ reaction to these infections. I investigated the immune responses of the different mosquito cells to Bunyamwera virus infection, in particular antimicrobial signaling pathways (Toll and IMD) and RNA interference (RNAi). The data obtained in U4.4 cells suggest that NSs plays an important role in the infection of mosquitoes. Moreover infection of U4.4 cells more closely resembles infection in Ae and A20 cells and live Aedes aegypti mosquitoes. My data showed that the investigated cell lines have various properties, and therefore they can be used to study different aspects of mosquito-virus interactions.

2011-01-01T00:00:00Z Szemiel, Agnieszka M. The Bunyaviridae family is one of the largest among RNA viruses, comprising more than 350 serologically distinct viruses. The family is classified into five genera, Orthobunyavirus, Hantavirus, Nairovirus, Phlebovirus, and Tospovirus. Orthobunyaviruses, nairoviruses and phleboviruses are maintained in nature by a propagative cycle involving blood-feeding arthropods and susceptible vertebrate hosts. Like most arthropod-borne viruses, bunyavirus replication causes little damage to the vector, whereas infection of the mammalian host may lead to death. This situation is mimicked in the laboratory: in cultured mosquito cells no cytopathology is observed and a persistent infection is established, whereas in cultured mammalian cells orthobunyavirus infection is lytic and leads to cell death. Bunyaviruses encode four common structural proteins: an RNA-dependent RNA polymerase, two glycoproteins (Gc and Gn), and a nucleoprotein N. Some viruses also code for nonstructural proteins called NSm and NSs. The NSs protein of the prototype bunyavirus, Bunyamwera virus, seems to be one of the factors responsible for the different outcomes of infection in mammalian and mosquito cell lines. However, only limited information is available on the growth of bunyaviruses in cultured mosquito cell lines other than Aedes albopictus C6/36 cells. Here, I compared the replication of Bunyamwera virus in two additional Aedes albopictus cell clones, C7-10 and U4.4, and two Aedes aegypti cell clones, Ae and A20, and investigated the impact of virus replication on cell function. In addition, whereas the vertebrate innate immune response to arbovirus infection is well studied, relatively little is known about mosquitoes’ reaction to these infections. I investigated the immune responses of the different mosquito cells to Bunyamwera virus infection, in particular antimicrobial signaling pathways (Toll and IMD) and RNA interference (RNAi). The data obtained in U4.4 cells suggest that NSs plays an important role in the infection of mosquitoes. Moreover infection of U4.4 cells more closely resembles infection in Ae and A20 cells and live Aedes aegypti mosquitoes. My data showed that the investigated cell lines have various properties, and therefore they can be used to study different aspects of mosquito-virus interactions. Harris, Mark R. http://hdl.handle.net/10023/881 2012-10-19T14:07:50Z 2010-06-23T00:00:00Z

Abstract: Antimicrobial peptides (AMPs) are found throughout the animal kingdom and act as a natural defence against a broad spectrum of pathogens. These peptides are toxic to invading organisms without acting on host cells, so are of interest for their potential to act as potent new drugs against pathogenic organisms. AMPs traverse the cell wall and predominantly target the plasma membrane, resulting in destabilisation, leakage of intracellular components and cell death. In this thesis the mode of action of several AMPs was investigated. The role of the cell wall was studied and found to mediate peptide binding, the inhibition of certain cell wall components also increased peptide action, subsequent internalisation events were observed with varying localisation patterns and the effect of several genes that alter cell susceptibility to AMP were examined. Several Candida albicans mutants, each deficient in cell wall protein mannosylation, were tested in relation to their susceptibility to AMPs. It was discovered that cells lacking or deficient in the phosphomannan fraction, with a concomitant reduction in surface negative charge, correlated with reduced susceptibility to AMP action. To ascertain whether peptide binds to negatively charged phosphate, the effect of exogenous glucosamine 6-phosphate (but not glucosamine hydrochloride) was studied demonstrating that peptide efficacy was reduced due to the presence of exogenous phosphate. More specifically, sequestration of the truncated cationic AMP dermaseptin S3 (DsS3(1-16)) was reduced in these phosphomannan deficient mutants. Microscopy analysis of fluorescein tagged DsS3(1-16) also revealed the differential localisation patterns of this AMP: transiently binding to the plasma membrane, localisation to the vacuole or diffuse distribution throughout the cytoplasm. It is proposed that for these cationic AMPs to exert their full antifungal action they must first bind to the negatively charged phosphate. The echinocandins are a relatively new class of antifungal that function by inhibiting 1,3-β glucan synthase resulting in reduced 1,3-β glucan in the cell wall. As AMPs have to traverse the cell wall it was postulated that cells lacking this fraction would display increased AMP binding to the membrane. Clinical isolate strains of Candida and Cryptococcus spp. were acquired to test their susceptibility to AMP and echinocandin combinations. Comparing the fractional inhibitory concentration index (FICI) (supported by viable cell counts and on a solid surface using disc diffusion assays) synergy was observed between caspofungin, anidulafungin and several AMPs in vitro. In vitro toxicity assays revealed no increase in haemolytic or cytotoxic action on combination. These synergistic combinations could provide a novel treatment against fungal pathogens. The final area of study was based upon work that identified genes whose expression altered cell susceptibility to AMPs. Three genes were selected for investigation that upon deletion increased the action of DsS3(1-16) or magainin 2 on S. cerevisiae. Results from growth analysis, peptide sequestration and cell viability counts confirmed that deletion of HAL5, LDB7 or IMP2’ did increase susceptibility. Additionally, deletion of HAL5 increased the probability of cell depolarisation upon peptide exposure. Expression of GFP-tagged Imp2’ also increased when cells were exposed to DsS3(1-16). It was concluded that deletion of HAL5 increases depolarisation due to insufficient potassium efflux, leading to ion leakage and cell death facilitated by AMP action. Double strand break repair and DNA protection are probably compromised upon deletion of LDB7 and IMP2’, increasing the inhibitory action of DsS3(1-16) that has previously been shown to bind to DNA. Description: Electronic version does not contain associated previously published material

2010-06-23T00:00:00Z Harris, Mark R. Antimicrobial peptides (AMPs) are found throughout the animal kingdom and act as a natural defence against a broad spectrum of pathogens. These peptides are toxic to invading organisms without acting on host cells, so are of interest for their potential to act as potent new drugs against pathogenic organisms. AMPs traverse the cell wall and predominantly target the plasma membrane, resulting in destabilisation, leakage of intracellular components and cell death. In this thesis the mode of action of several AMPs was investigated. The role of the cell wall was studied and found to mediate peptide binding, the inhibition of certain cell wall components also increased peptide action, subsequent internalisation events were observed with varying localisation patterns and the effect of several genes that alter cell susceptibility to AMP were examined. Several Candida albicans mutants, each deficient in cell wall protein mannosylation, were tested in relation to their susceptibility to AMPs. It was discovered that cells lacking or deficient in the phosphomannan fraction, with a concomitant reduction in surface negative charge, correlated with reduced susceptibility to AMP action. To ascertain whether peptide binds to negatively charged phosphate, the effect of exogenous glucosamine 6-phosphate (but not glucosamine hydrochloride) was studied demonstrating that peptide efficacy was reduced due to the presence of exogenous phosphate. More specifically, sequestration of the truncated cationic AMP dermaseptin S3 (DsS3(1-16)) was reduced in these phosphomannan deficient mutants. Microscopy analysis of fluorescein tagged DsS3(1-16) also revealed the differential localisation patterns of this AMP: transiently binding to the plasma membrane, localisation to the vacuole or diffuse distribution throughout the cytoplasm. It is proposed that for these cationic AMPs to exert their full antifungal action they must first bind to the negatively charged phosphate. The echinocandins are a relatively new class of antifungal that function by inhibiting 1,3-β glucan synthase resulting in reduced 1,3-β glucan in the cell wall. As AMPs have to traverse the cell wall it was postulated that cells lacking this fraction would display increased AMP binding to the membrane. Clinical isolate strains of Candida and Cryptococcus spp. were acquired to test their susceptibility to AMP and echinocandin combinations. Comparing the fractional inhibitory concentration index (FICI) (supported by viable cell counts and on a solid surface using disc diffusion assays) synergy was observed between caspofungin, anidulafungin and several AMPs in vitro. In vitro toxicity assays revealed no increase in haemolytic or cytotoxic action on combination. These synergistic combinations could provide a novel treatment against fungal pathogens. The final area of study was based upon work that identified genes whose expression altered cell susceptibility to AMPs. Three genes were selected for investigation that upon deletion increased the action of DsS3(1-16) or magainin 2 on S. cerevisiae. Results from growth analysis, peptide sequestration and cell viability counts confirmed that deletion of HAL5, LDB7 or IMP2’ did increase susceptibility. Additionally, deletion of HAL5 increased the probability of cell depolarisation upon peptide exposure. Expression of GFP-tagged Imp2’ also increased when cells were exposed to DsS3(1-16). It was concluded that deletion of HAL5 increases depolarisation due to insufficient potassium efflux, leading to ion leakage and cell death facilitated by AMP action. Double strand break repair and DNA protection are probably compromised upon deletion of LDB7 and IMP2’, increasing the inhibitory action of DsS3(1-16) that has previously been shown to bind to DNA. Murray, Ross George http://hdl.handle.net/10023/571 2013-05-07T14:24:59Z 2008-06-25T00:00:00Z

Abstract: The Bucherer-Bergs reaction is a classical multi-component reaction that yields hydantoins, which can be hydrolysed to afford α-amino acids. Hydantoins have many uses in modern organic synthesis, and this moiety has been included in a number of therapeutic agents, which have a wide range of biological activities. Herein, we report a mild synthesis of 5- and 5,5-substituted hydantoins from α-aminonitriles using Hünig’s base and carbon dioxide. This reaction can be performed in excellent yields, using a variety of organic solvents and is applicable to a range of substrates. In an extension to the above methodology, a one-pot Lewis acid-catalysed synthesis of hydantoins from ketones has also been developed and optimised in organic media. This reaction can be performed in excellent yields and is suitable for the synthesis of 5- and 5,5-substituted hydantoins.

2008-06-25T00:00:00Z Murray, Ross George The Bucherer-Bergs reaction is a classical multi-component reaction that yields hydantoins, which can be hydrolysed to afford α-amino acids. Hydantoins have many uses in modern organic synthesis, and this moiety has been included in a number of therapeutic agents, which have a wide range of biological activities. Herein, we report a mild synthesis of 5- and 5,5-substituted hydantoins from α-aminonitriles using Hünig’s base and carbon dioxide. This reaction can be performed in excellent yields, using a variety of organic solvents and is applicable to a range of substrates. In an extension to the above methodology, a one-pot Lewis acid-catalysed synthesis of hydantoins from ketones has also been developed and optimised in organic media. This reaction can be performed in excellent yields and is suitable for the synthesis of 5- and 5,5-substituted hydantoins. Eifan, Saleh A. http://hdl.handle.net/10023/542 2012-04-27T11:49:47Z 2008-01-01T00:00:00Z

Abstract: Bunyamwera virus (BUNV) is the prototype of the family Bunyaviridae. It has a tripartite genome consisting of negative sense RNA segments called large (L), medium (M) and small (S). The S segment encodes the nucleocapsid protein (N) of 233 amino acids. The N protein encapsidates all three segments to form transcriptionally active ribonucleoproteins (RNPs). The aim of this project was to determine the domain map of BUNV N protein. To investigate residues in BUNV N crucial for its functionality, random and site- specific mutagenesis were performed on a cDNA clone encoding the BUNV N protein. In total, 102 single amino acid substitutions were generated in the BUNV N protein sequence. All mutant N proteins were used in a BUNV minigenome system to compare their activity to wt BUNV N. The mutant proteins displayed a wide-range of activity, from parental-like to essentially inactive. The most disruptive mutations were R94A, I118N, W134A, Y141C, L177A, K179I and W193A. Sixty-four clones carrying single substitutions in the BUNV N protein were used in the BUNV rescue system in an attempt to recover viable mutant viruses. Fifty recombinant mutant viruses were rescued and 14 N genes were nonrescuable. The 50 mutant viruses were characterized by: titration, protein labelling, western blotting, temperature sensitivity and host-restriction. Mutant viruses displayed a wide range of titers between 10³ -10⁸ pfu/ml, and three different plaque sizes large, medium and small. Protein labelling and western blotting showed that mutations in the N gene did not affect expression of the other viral genes as much as affecting N protein expression. It was demonstrated that single amino acid substitutions could alter N protein electrophoretic mobility in SDS- PAGE (e.g. P19Q and L53F). Temperature sensitivity tests showed that recombinant viruses N74S, S96S, K228T and G230R were ts, growing at 33˚C but not at 37˚C or 38˚C, while the parental virus grew at all temperatures. Using the northern blotting technique, mutant viruses N74S and S96G were shown to have a ts defect in genome-synthesis (late replication step), while mutant viruses K228T and G230R had a ts defect in antigenome- synthesis (early replication step). Host-restriction experiments were performed using 5 different cell lines (Vero-E6, BHK-21, 2FTGH-V, A549-V and 293-V). Overall, the parental virus grew similarly in all cell lines. Likewise, the majority of mutant viruses follow this pattern except mutant virus Y23A. It showed a 100-fold reduction in titer in 2FTGH-V cells. Comparing the ratios of intracellular and extracellular particles revealed that only 15% of the total virus particles of mutant Y23A was released as extracellular particles compared to 30% of the parental virus. Fourteen N genes were nonrescuable. They were characterized by (i) their activity in the BUNV minigenome system, (ii) their activity in BUNV packaging assay, (iii) their ability to form multimers, (iv) their ability to interact with L protein, and (v) their impact on RNA synthesis. In summary, BUNV N protein was shown to be multi-functional and involved in the regulation of virus transcription and replication, RNA synthesis and assembly, via interactions with the viral L polymerase, RNA backbone, itself or the viral glycoproteins.

2008-01-01T00:00:00Z Eifan, Saleh A. Bunyamwera virus (BUNV) is the prototype of the family Bunyaviridae. It has a tripartite genome consisting of negative sense RNA segments called large (L), medium (M) and small (S). The S segment encodes the nucleocapsid protein (N) of 233 amino acids. The N protein encapsidates all three segments to form transcriptionally active ribonucleoproteins (RNPs). The aim of this project was to determine the domain map of BUNV N protein. To investigate residues in BUNV N crucial for its functionality, random and site- specific mutagenesis were performed on a cDNA clone encoding the BUNV N protein. In total, 102 single amino acid substitutions were generated in the BUNV N protein sequence. All mutant N proteins were used in a BUNV minigenome system to compare their activity to wt BUNV N. The mutant proteins displayed a wide-range of activity, from parental-like to essentially inactive. The most disruptive mutations were R94A, I118N, W134A, Y141C, L177A, K179I and W193A. Sixty-four clones carrying single substitutions in the BUNV N protein were used in the BUNV rescue system in an attempt to recover viable mutant viruses. Fifty recombinant mutant viruses were rescued and 14 N genes were nonrescuable. The 50 mutant viruses were characterized by: titration, protein labelling, western blotting, temperature sensitivity and host-restriction. Mutant viruses displayed a wide range of titers between 10³ -10⁸ pfu/ml, and three different plaque sizes large, medium and small. Protein labelling and western blotting showed that mutations in the N gene did not affect expression of the other viral genes as much as affecting N protein expression. It was demonstrated that single amino acid substitutions could alter N protein electrophoretic mobility in SDS- PAGE (e.g. P19Q and L53F). Temperature sensitivity tests showed that recombinant viruses N74S, S96S, K228T and G230R were ts, growing at 33˚C but not at 37˚C or 38˚C, while the parental virus grew at all temperatures. Using the northern blotting technique, mutant viruses N74S and S96G were shown to have a ts defect in genome-synthesis (late replication step), while mutant viruses K228T and G230R had a ts defect in antigenome- synthesis (early replication step). Host-restriction experiments were performed using 5 different cell lines (Vero-E6, BHK-21, 2FTGH-V, A549-V and 293-V). Overall, the parental virus grew similarly in all cell lines. Likewise, the majority of mutant viruses follow this pattern except mutant virus Y23A. It showed a 100-fold reduction in titer in 2FTGH-V cells. Comparing the ratios of intracellular and extracellular particles revealed that only 15% of the total virus particles of mutant Y23A was released as extracellular particles compared to 30% of the parental virus. Fourteen N genes were nonrescuable. They were characterized by (i) their activity in the BUNV minigenome system, (ii) their activity in BUNV packaging assay, (iii) their ability to form multimers, (iv) their ability to interact with L protein, and (v) their impact on RNA synthesis. In summary, BUNV N protein was shown to be multi-functional and involved in the regulation of virus transcription and replication, RNA synthesis and assembly, via interactions with the viral L polymerase, RNA backbone, itself or the viral glycoproteins. Mackay, Dale Tara http://hdl.handle.net/10023/468 2012-12-10T15:47:19Z 2008-06-27T00:00:00Z

Abstract: 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.

2008-06-27T00:00:00Z Mackay, Dale Tara 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.