Publicação

Lysis strategy of Streptococcus pneumoniae bacteriophages : mechanisms and host implications

Detalhes bibliográficos
Resumo:	Bacteriophages (phages), the most abundant entities in the biosphere, play a central role in the shaping of natural populations of bacteria. Phages have also been the focus of several studies due to their potential as tools for therapeutic purposes. Notably, detailed analysis carried out in different bacterial species established that phages have a prominent influence in virulence. The abundance of lysogenic phages in Streptococcus pneumoniae isolates associated with infection was suggested some years ago, and recently, it has been proposed that lysogens account for as much as 76% of the samples analyzed. However, the role of pneumococcal prophages in the pathogenic potential of its host remains so far unknown. Bacterial lysis promoted by the major autolysin LytA has been implicated in the capacity of pneumococcus to cause infection, essentially due to the release of proinflammatory cell wall compounds and intracellular virulence factors. Even if no phage-encoded virulence factors were ever found, prophage-mediated host lysis by itself may contribute significantly to pneumococcal pathogenesis. Therefore, investigating the phage lysis system is clearly important in furthering our understanding of this effect. This work explores the exact mechanism underlying the lysis strategy of S. pneumoniae phages to release their progeny and also the implications of lysogeny, particularly due to induced cell lysis, in the host ability to form biofilms, a bacterial lifestyle associated with pneumococcal human infections. Pneumococcal phages lyse their bacterial hosts, and consequently release the newly formed phage particles, at the end of the vegetative cycle through the combined action of holins that form lesions in the cytoplasmic membrane and lysins that degrade the bacterial peptidoglycan. The powerful lytic activity of the S. pneumoniae autolysin raised the possibility that it could play an important role in this process. By deleting the bacterial and phage lysins in both lysogenic and lysogenized strains, the contribution of LytA to phage release was evaluated based on bacterial culture lysis monitoring and phage plaque assays. It was found that, independently of the host genetic background, the bacterial autolysin is activated during phage-mediated lysis. Flow cytometry assessment of the membrane integrity after phage induction revealed that LytA triggering results from holininduced membrane disruption, similarly to the activation of the phage lysin. These results provide evidence that the energy status of the membrane may be involved in autolysin regulation at the cell surface. 3 We were able to demonstrate that, in the absence of the phage lytic enzyme, LytA by itself mediates extensive bacterial lysis, accompanied by the release of a large amount of fully functional phages capable of completing their life cycle since phage plaques were clearly detected. The overwhelming majority of phages of other bacterial species are absolutely incapable of bacterial lysis, trapping the phage progeny within the host cell, when the genes encoding lysins are deleted. Moreover, those rare mutants that bring about lysis depend only on phage-encoded factors. Nevertheless, exclusive dependence on the autolysin delayed the lysis timing and reduced the lysis extent. Accordingly, phage plaques were detected later than those in the presence of both host and phage lysins and a significant decrease on the number of virions released was observed. Therefore, lysis strictly dependent on LytA can lead to phage fitness impairment by retaining phage progeny longer within the host and reducing the amount of particles that actually escapes from entrapment. Nonetheless, under normal conditions, it was found that the concurrent activation of LytA with the phage lysin increases the total number of phages that exit the cell when the infective cycle is completed. Hence, pneumococcal phages use the ubiquitous host autolysin to accomplish an optimal phage exiting strategy and are unique among lysin-equipped phages in their dependence on bacterial lytic factors to achieve such task. Although the function of holin and phage lysin is characterized, the interplay between them to achieve lysis in S. pneumoniae was never fully determined. It has been shown that pneumococcal phage lysins are structurally and functionally similar to LytA, thus, they may share the same cellular localization and control mechanisms. Our finding that holin-induced membrane lesions trigger the bacterial cell wall autolysin prompted a deeper study of the pneumococcal lysis strategy. For this purpose, deletions of the holin and autolysin were performed in a lysogenic strain, in which the resident phage has a typical holin-lysin cassette. In the absence of these functions, western blot analysis and the effect of membrane permeabilizing and proton motive force (pmf)-dissipating agents on culture lysis allowed concluding that pneumococcal phage lysins accumulate with time across the lytic cycle and are continuously targeted to the cell wall. The phage lysin remains inactive associated with the choline residues within this structure. Therefore, the access of pneumococcal phage lysins to the bacterial surface is holin independent, hence they can be classified as exolysins. These findings are in contrast to what is observed in the large majority of holin-lysin phages where endolysins accumulate in the cytoplasm since they lack an intrinsic secretory signal sequence and consequently depend on holins to reach the peptidoglycan target. In addition, the involvement of the host Sec pathway in the phage lysin export was investigated. We assessed the cell wall localization of the phage 4 lysin by the same experimental procedures after culture treatment with the Sec inhibitor sodium azide. It was found that the phage lytic enzyme is possibly exported by the Sec system of pneumococci in spite of the striking absence of a signal sequence that could target it to the extracytoplasmic environment. This may constitute the first evidence, on phages encoding only holins and lysins in their lytic cassettes, of an exolysin without a secretion signal that is translocated through the membrane by the host Sec machinery. Furthermore, since the cell wall located autolysin also lacks obvious motifs or signals for an external localization, these results may provide clues for its transport mechanism. Dependence exclusively on the pmf-dissipating agent for complete host lysis, together with the previous observation of holin’s permeabilizing effect, showed that collapse of the cytoplasmic membrane electrochemical gradient achieved by the holins is the triggering signal to activate the phage lysin. In this study, it was further confirmed that activation of the externalized bacterial autolysin LytA, previously shown to contribute to phage progeny release, is also equally related to perturbations on the energized membrane. Thus, these results demonstrate that in S. pneumoniae phages, holin is not required for lysin export but is crucial to trigger the phage and bacterial lysins already residing in the cell wall by pmf dissipation upon formation of lesions on the membrane. In this regard, holins are the timing device that dictates when lysis takes place. After the characterization of the phage lytic mechanism, the contribution of lysis mediated by lysogenic phages to pneumococcal biofilms was investigated. S. pneumoniae lysogens are associated with human infections and pneumococcal biofilms have been implicated both in colonization and infection. It was explored if prophage spontaneous induction and consequent bacterial lysis enhance pneumococcal biofilm development providing a source of extracellular DNA (eDNA), a major factor in the biofilm matrix. Monitoring biofilm growth of lysogens and nonlysogenic bacteria by biomass quantification, viable cell counts and confocal laser scanning microscopy (CLSM), indicated that lysogenic bacteria are more prone to form biofilms, yielding structures with higher biomass and cell viability and showing denser biofilms in CLSM. Spontaneous phage induction was demonstrated to occur continuously as phages could be detected throughout biofilm formation through measurement of the total number of PFUs (plaque forming units) at specific time points. When comparing biofilm development between wild-type lysogens and those deleted in the phage lysin, bacterial autolysin LytA or both lysins, it was observed that phagemediated lytic events influence positively the biofilm structure. These results established that prophage promotes biofilm development due to bacterial lysis upon spontaneous induction. In 5 agreement, lysis inside biofilms also occurs in other bacterial species and it might be related to increased biofilm fitness. However, the effects created by the ablation of either the phage or bacterial lysins were overcome by the addition of external DNA. Additionally, in independent experiments, it was found that treatment with DNase I resulted in sparser and thinner biofilms while supplementation with DNA resulted in a thicker and more densely packed structure, confirming the important role of eDNA in pneumococcal biofilms. The quantification of eDNA released within these structures by real-time PCR also supported that lytic events promoted by phage are an important source of this matrix component, as biofilms of lytic strains contained more eDNA than those of nonlytic strains. Therefore, limited phage-mediated host lysis constitutes an important source of eDNA in S. pneumoniae biofilms favoring biofilm formation by lysogenic strains. Interestingly, massive phage induction leading to a high proportion of lysis was observed to disrupt severely biofilms of pneumococcal lysogens with a significant decrease in biofilm mass confirmed by CLSM visualization. These findings corroborate previous studies that show the potential use of lytic phages to destroy bacterial biofilms. The presented results and conclusions are of great value not only to directly increase our knowledge on phage biology and their relationship with the host bacteria, but ultimately to uncover the role of lysogeny in pneumococcal virulence. In this context, massive prophageinduced lysis of the host could mimic the major bacterial autolysin by releasing factors known to contribute to the course of infection. On the other hand, lysis due to spontaneous levels of induction, characteristic of prophage carriage, may have an impact in pathogenesis by enhancing S. pneumoniae biofilm formation, which has been implicated in the processes of colonization and disease. A deeper understanding of the mechanisms underlying pneumococcal infection is of vital significance to manage this important human pathogen.
Autores principais:	Frias, Maria João
Assunto:	Streptococcus pneumoniae Bacteriófagos Lisina Teses de doutoramento - 2011
Ano:	2011
País:	Portugal
Tipo de documento:	tese de doutoramento
Tipo de acesso:	acesso aberto
Instituição associada:	Universidade de Lisboa
Idioma:	inglês
Origem:	Repositório da Universidade de Lisboa

Descrição
Resumo:	Bacteriophages (phages), the most abundant entities in the biosphere, play a central role in the shaping of natural populations of bacteria. Phages have also been the focus of several studies due to their potential as tools for therapeutic purposes. Notably, detailed analysis carried out in different bacterial species established that phages have a prominent influence in virulence. The abundance of lysogenic phages in Streptococcus pneumoniae isolates associated with infection was suggested some years ago, and recently, it has been proposed that lysogens account for as much as 76% of the samples analyzed. However, the role of pneumococcal prophages in the pathogenic potential of its host remains so far unknown. Bacterial lysis promoted by the major autolysin LytA has been implicated in the capacity of pneumococcus to cause infection, essentially due to the release of proinflammatory cell wall compounds and intracellular virulence factors. Even if no phage-encoded virulence factors were ever found, prophage-mediated host lysis by itself may contribute significantly to pneumococcal pathogenesis. Therefore, investigating the phage lysis system is clearly important in furthering our understanding of this effect. This work explores the exact mechanism underlying the lysis strategy of S. pneumoniae phages to release their progeny and also the implications of lysogeny, particularly due to induced cell lysis, in the host ability to form biofilms, a bacterial lifestyle associated with pneumococcal human infections. Pneumococcal phages lyse their bacterial hosts, and consequently release the newly formed phage particles, at the end of the vegetative cycle through the combined action of holins that form lesions in the cytoplasmic membrane and lysins that degrade the bacterial peptidoglycan. The powerful lytic activity of the S. pneumoniae autolysin raised the possibility that it could play an important role in this process. By deleting the bacterial and phage lysins in both lysogenic and lysogenized strains, the contribution of LytA to phage release was evaluated based on bacterial culture lysis monitoring and phage plaque assays. It was found that, independently of the host genetic background, the bacterial autolysin is activated during phage-mediated lysis. Flow cytometry assessment of the membrane integrity after phage induction revealed that LytA triggering results from holininduced membrane disruption, similarly to the activation of the phage lysin. These results provide evidence that the energy status of the membrane may be involved in autolysin regulation at the cell surface. 3 We were able to demonstrate that, in the absence of the phage lytic enzyme, LytA by itself mediates extensive bacterial lysis, accompanied by the release of a large amount of fully functional phages capable of completing their life cycle since phage plaques were clearly detected. The overwhelming majority of phages of other bacterial species are absolutely incapable of bacterial lysis, trapping the phage progeny within the host cell, when the genes encoding lysins are deleted. Moreover, those rare mutants that bring about lysis depend only on phage-encoded factors. Nevertheless, exclusive dependence on the autolysin delayed the lysis timing and reduced the lysis extent. Accordingly, phage plaques were detected later than those in the presence of both host and phage lysins and a significant decrease on the number of virions released was observed. Therefore, lysis strictly dependent on LytA can lead to phage fitness impairment by retaining phage progeny longer within the host and reducing the amount of particles that actually escapes from entrapment. Nonetheless, under normal conditions, it was found that the concurrent activation of LytA with the phage lysin increases the total number of phages that exit the cell when the infective cycle is completed. Hence, pneumococcal phages use the ubiquitous host autolysin to accomplish an optimal phage exiting strategy and are unique among lysin-equipped phages in their dependence on bacterial lytic factors to achieve such task. Although the function of holin and phage lysin is characterized, the interplay between them to achieve lysis in S. pneumoniae was never fully determined. It has been shown that pneumococcal phage lysins are structurally and functionally similar to LytA, thus, they may share the same cellular localization and control mechanisms. Our finding that holin-induced membrane lesions trigger the bacterial cell wall autolysin prompted a deeper study of the pneumococcal lysis strategy. For this purpose, deletions of the holin and autolysin were performed in a lysogenic strain, in which the resident phage has a typical holin-lysin cassette. In the absence of these functions, western blot analysis and the effect of membrane permeabilizing and proton motive force (pmf)-dissipating agents on culture lysis allowed concluding that pneumococcal phage lysins accumulate with time across the lytic cycle and are continuously targeted to the cell wall. The phage lysin remains inactive associated with the choline residues within this structure. Therefore, the access of pneumococcal phage lysins to the bacterial surface is holin independent, hence they can be classified as exolysins. These findings are in contrast to what is observed in the large majority of holin-lysin phages where endolysins accumulate in the cytoplasm since they lack an intrinsic secretory signal sequence and consequently depend on holins to reach the peptidoglycan target. In addition, the involvement of the host Sec pathway in the phage lysin export was investigated. We assessed the cell wall localization of the phage 4 lysin by the same experimental procedures after culture treatment with the Sec inhibitor sodium azide. It was found that the phage lytic enzyme is possibly exported by the Sec system of pneumococci in spite of the striking absence of a signal sequence that could target it to the extracytoplasmic environment. This may constitute the first evidence, on phages encoding only holins and lysins in their lytic cassettes, of an exolysin without a secretion signal that is translocated through the membrane by the host Sec machinery. Furthermore, since the cell wall located autolysin also lacks obvious motifs or signals for an external localization, these results may provide clues for its transport mechanism. Dependence exclusively on the pmf-dissipating agent for complete host lysis, together with the previous observation of holin’s permeabilizing effect, showed that collapse of the cytoplasmic membrane electrochemical gradient achieved by the holins is the triggering signal to activate the phage lysin. In this study, it was further confirmed that activation of the externalized bacterial autolysin LytA, previously shown to contribute to phage progeny release, is also equally related to perturbations on the energized membrane. Thus, these results demonstrate that in S. pneumoniae phages, holin is not required for lysin export but is crucial to trigger the phage and bacterial lysins already residing in the cell wall by pmf dissipation upon formation of lesions on the membrane. In this regard, holins are the timing device that dictates when lysis takes place. After the characterization of the phage lytic mechanism, the contribution of lysis mediated by lysogenic phages to pneumococcal biofilms was investigated. S. pneumoniae lysogens are associated with human infections and pneumococcal biofilms have been implicated both in colonization and infection. It was explored if prophage spontaneous induction and consequent bacterial lysis enhance pneumococcal biofilm development providing a source of extracellular DNA (eDNA), a major factor in the biofilm matrix. Monitoring biofilm growth of lysogens and nonlysogenic bacteria by biomass quantification, viable cell counts and confocal laser scanning microscopy (CLSM), indicated that lysogenic bacteria are more prone to form biofilms, yielding structures with higher biomass and cell viability and showing denser biofilms in CLSM. Spontaneous phage induction was demonstrated to occur continuously as phages could be detected throughout biofilm formation through measurement of the total number of PFUs (plaque forming units) at specific time points. When comparing biofilm development between wild-type lysogens and those deleted in the phage lysin, bacterial autolysin LytA or both lysins, it was observed that phagemediated lytic events influence positively the biofilm structure. These results established that prophage promotes biofilm development due to bacterial lysis upon spontaneous induction. In 5 agreement, lysis inside biofilms also occurs in other bacterial species and it might be related to increased biofilm fitness. However, the effects created by the ablation of either the phage or bacterial lysins were overcome by the addition of external DNA. Additionally, in independent experiments, it was found that treatment with DNase I resulted in sparser and thinner biofilms while supplementation with DNA resulted in a thicker and more densely packed structure, confirming the important role of eDNA in pneumococcal biofilms. The quantification of eDNA released within these structures by real-time PCR also supported that lytic events promoted by phage are an important source of this matrix component, as biofilms of lytic strains contained more eDNA than those of nonlytic strains. Therefore, limited phage-mediated host lysis constitutes an important source of eDNA in S. pneumoniae biofilms favoring biofilm formation by lysogenic strains. Interestingly, massive phage induction leading to a high proportion of lysis was observed to disrupt severely biofilms of pneumococcal lysogens with a significant decrease in biofilm mass confirmed by CLSM visualization. These findings corroborate previous studies that show the potential use of lytic phages to destroy bacterial biofilms. The presented results and conclusions are of great value not only to directly increase our knowledge on phage biology and their relationship with the host bacteria, but ultimately to uncover the role of lysogeny in pneumococcal virulence. In this context, massive prophageinduced lysis of the host could mimic the major bacterial autolysin by releasing factors known to contribute to the course of infection. On the other hand, lysis due to spontaneous levels of induction, characteristic of prophage carriage, may have an impact in pathogenesis by enhancing S. pneumoniae biofilm formation, which has been implicated in the processes of colonization and disease. A deeper understanding of the mechanisms underlying pneumococcal infection is of vital significance to manage this important human pathogen.