Complete Genome Sequence of Staphylococcus aureus Bacteriophage GH15

GH15 is a polyvalent phage that shows activity against a wide range of Staphylococcus aureus strains. In this work, the complete genome sequence of GH15 was determined. With a genome size of 139,806 bp (double-stranded DNA), GH15 is the largest staphylococcal phage sequenced to date. The complete genome encodes 214 open reading frames (ORFs) and 4 tRNAs. The closest relatives are the class III staphylococcal myobacteriophages, including K, A5W, ISP, Sb-1, and G1. Interestingly, although corresponding gene sequences demonstrate very high similarity, all the introns and inteins present in the phages listed above are absent in GH15. As such, GH15 can be considered phylogenetically unique among the staphylococcal myobacteriophages, indicating the diversity of this family.     

The role of human immortal skin keratinocytes-acellular dermal matrix scaffold in skin repair and regeneration

In this study, we aimed to investigate the phenotypic characteristics of human immortal skin keratinocytes (HaCaT) cells and the role of acellular dermal matrix (ADM) in coculture system of HaCaT cells and ADM. Flow cytometry was used to examine the cluster of differentiation (CD) makers of HaCaT cells. Apoptosis analysis was applied to detect the apoptosis rate of HaCaT cells. Morphological observation of ADM isolated from the reticular layer of Sprague-Dawley rat dermis was utilized to evaluate the morphological structure of ADM. Methylthiazolyl tetrazolium (MTT) assay and morphological experiments were further used to confirm the scaffold role of ADM in HaCaT cells. A wound-healing mice model accompanied by HaCaT-ADM scaffold transplantation was performed to further verify the function of HaCaT-ADM scaffold. Our results showed that CD71, CD49f, K19, and CD29 were highly expressed in HaCaT cells, and the percentage of apoptosis cells was significantly increased, which represented that HaCaT cells had much stronger capacities of adhesion and proliferation than normal human keratinocytes. Additionally, the morphological structure of ADM presented many natural microbores, which made cells rapidly grow on ADM. The results exhibited that the HaCaT cells indeed promptly proliferate on ADM and easily grow into the microbores of ADM. Finally, an in vivo experiment further confirmed that the transplantation of the HaCaT-ADM scaffold into the dorsal skin of a wound-healing mice model could gradually repair the injured wound. Thus, these findings indicated that HaCaT cells might be as seed cells to develop skin tissue engineering and the HaCaT-ADM scaffold might be a better candidate to promote skin repair and regeneration.     

A guard-killer phage cocktail effectively lyses the host and inhibits the development of phage-resistant strains of Escherichia coli

In recent years, after the emergence of a large number of multidrug-resistant bacteria, phages and phage-associated products for the prevention and control of bacterial disease have revealed prominent advantages as compared with antibiotics. However, bacteria are susceptible to becoming phage-resistant, thus severely limiting the application of phage therapy. In this study, Escherichia coli cells were incubated with lytic bacteriophages to obtain mutants that were resistant to the lytic phages. Then, bacteriophages against the phage-resistant variants were isolated and subsequently mixed with the original lytic phage to prepare a novel phage cocktail for bactericidal use. The data showed that our phage cocktail not only had notable bactericidal effects, including a widened host range and rapid lysis, but also decreased the generation and mutation frequency of phage-resistant strains in vitro. In addition, we tested our cocktail in a murine bacteremia model. The results suggested that compared with the single phage, fewer phage-resistant bacteria appeared during the treatment of phage cocktail, thus prolonging the usable time of the phage cocktail and improving its therapeutic effect in phage applications. Importantly, our preparation method of phage cocktail was proved to be generalizable. Because the bacteriophage against the phage-resistant strain is an ideal guard that promptly attacks potential phage resistance, this guard-killer dual-function phage cocktail provides a novel strategy for phage therapy that allows the natural ecology to be sustained.

     

Structural and Biochemical Characterization Reveals LysGH15 as an Unprecedented “EF-Hand-Like” Calcium-Binding Phage Lysin

The lysin LysGH15, which is derived from the staphylococcal phage GH15, demonstrates a wide lytic spectrum and strong lytic activity against methicillin-resistant Staphylococcus aureus (MRSA). Here, we find that the lytic activity of the full-length LysGH15 and its CHAP domain is dependent on calcium ions. To elucidate the molecular mechanism, the structures of three individual domains of LysGH15 were determined. Unexpectedly, the crystal structure of the LysGH15 CHAP domain reveals an “EF-hand-like” calcium-binding site near the Cys-His-Glu-Asn quartet active site groove. To date, the calcium-binding site in the LysGH15 CHAP domain is unique among homologous proteins, and it represents the first reported calcium-binding site in the CHAP family. More importantly, the calcium ion plays an important role as a switch that modulates the CHAP domain between the active and inactive states. Structure-guided mutagenesis of the amidase-2 domain reveals that both the zinc ion and E282 are required in catalysis and enable us to propose a catalytic mechanism. Nuclear magnetic resonance (NMR) spectroscopy and titration-guided mutagenesis identify residues (e.g., N404, Y406, G407, and T408) in the SH3b domain that are involved in the interactions with the substrate. To the best of our knowledge, our results constitute the first structural information on the biochemical features of a staphylococcal phage lysin and represent a pivotal step forward in understanding this type of lysin.     

Insights from ecological niche modeling on the taxonomic distinction and niche differentiation between the black‐spotted and red‐spotted tokay geckoes (Gekko gecko)

The black‐spotted tokay and the red‐spotted tokay are morphologically distinct and have largely allopatric distributions. The black‐spotted tokay is characterized by a small body size and dark skin with sundry spots, while the red‐spotted tokay has a relatively large body size and red spots. Based on morphological, karyotypic, genetic, and distribution differences, recent studies suggested their species status; however, their classifications remain controversial, and additional data such as ecological niches are necessary to establish firm hypotheses regarding their taxonomic status. We reconstructed their ecological niches models using climatic and geographic data. We then performed niche similarity tests (niche identity and background tests) and point‐based analyses to explore whether ecological differentiation has occurred, and whether such differences are sufficient to explain the maintenance of their separate segments of environmental ranges. We found that both niche models of the black‐ and the red‐spotted tokay had a good fit and a robust performance, as indicated by the high area under the curve (AUC) values (“black” = 0.982, SD = ± 0.002, “red” = 0.966 ± 0.02). Significant ecological differentiation across the entire geographic range was found, indicating that the involvement of ecological differentiation is important for species differentiation. Divergence along the environmental axes is highly associated with climatic conditions, with isothermality being important for the “black” form, while temperature seasonality, precipitation of warmest quarter, and annual temperature range together being important for the “red” form. These factors are likely important factors in niche differentiation between the two forms, which result in morphological replacement. Overall, beside morphological and genetic differentiation information, our results contribute to additional insights into taxonomic distinction and niche differentiation between the black‐ and the red‐spotted tokay.     

The antibacterial activity of <Emphasis Type="Italic">E. coli</Emphasis> bacteriophage lysin lysep3 is enhanced by fusing the <Emphasis Type="Italic">Bacillus amyloliquefaciens</Emphasis> bacteriophage endolysin binding domain D8 to the C-terminal region

Bacteriophage endolysin is one of the most promising antibiotic substitutes, but in Gram-negative bacteria, the outer membrane prevents the lysin from hydrolyzing peptidoglycans and blocks the development of lysin applications. The prime strategy for new antibiotic substitutes is allowing lysin to access the peptidoglycan from outside of the bacteria by reformation of the lysin. In this study, the novel Escherichia coli (E. coli) phage lyase lysep3, which lacks outside-in catalytic ability, was fused with the N-terminal region of the Bacillus amyloliquefaciens lysin including its cell wall binding domain D8 through the best manner of protein fusion based on the predicted tertiary structure of lysep3-D8 to obtain an engineered lysin that can lyse bacteria from the outside. Our results showed that lysep3-D8 could lyse both Gramnegative and Gram-positive bacteria, whereas lysep3 and D8 have no impact on bacterial growth. The MIC of lysep3-D8 on E. coli CVCC1418 is 60 μg/ml; lysep3-D8 can inhibit the growth of bacteria up to 12 h at this concentration. The bactericidal spectrum of lysep3-D8 is broad, as it can lyse of all of 14 E. coli strains, 3 P. aeruginosa strains, 1 Acinetobacter baumannii strain, and 1 Streptococcus strain. Lysep3-D8 has sufficient bactericidal effects on the 14 E. coli strains tested at the concentration of 100 μg/ml. The cell wall binding domain of the engineered lysin can destroy the integrity of the outer membrane of bacteria, thus allowing the catalytic domain to reach its target, peptidoglycan, to lyse the bacteria. Lysep3-D8 can be used as a preservative in fodder to benefit the health of animals. The method we used here proved to be a successful exploration of the reformation of phage lysin.     

茉莉C病毒侵染性克隆的构建及CP基序分析

【目的】构建茉莉C病毒(JaVC)福建分离物基因组全长cDNA侵染性克隆,克隆9省JaVC分离物的CP基因并比较分析基序差异,调查JaVC在我国茉莉产区的分布和传播情况。【方法】提取JaVC检测呈阳性的茉莉叶片总RNA,以反转录后的cDNA为模板扩增获得JaVC基因组全长序列并构建全长cDNA克隆pXT-JaVC-FJ;同时构建了外壳蛋白(coat protein,CP)融合红色荧光蛋白mCherry的克隆(pXT-JaVC CP-mCherry)。利用农杆菌浸润法侵染本生烟,通过RT-PCR检测法和激光共聚焦扫描显微镜观察法验证JaVC侵染性。克隆其他8省JaVC分离物的3''末端包含CP的片段并测序分析CP基序差异。通过田间调查明确JaVC在茉莉上的发生情况和其传播介体。【结果】pXT-JaVC-FJ浸润本生烟可引起系统侵染,说明该克隆具有侵染活性。所有JaVC分离物的CP均编码296个氨基酸,JaVC中国台湾分离物的CP与各分离物核苷酸序列相似性为82.27%‒91.36%,与广东分离物相似性最高;氨基酸序列相似性为92.23%‒96.82%,与云南分离物相似性最高;各分离物CP的氨基酸序列在32‒35位点上差异显著,具有6种不同的氨基酸基序排列,分别为SEHA、GENA、REGT、SENA、GGDA和GGNA。田间调查显示,JaVC在中国茉莉植株上广泛分布且可在蓟马中检测到JaVC。【结论】成功构建了JaVC-FJ的侵染性克隆,这为该病毒的基因功能、致病机理等研究奠定了基础;通过我国茉莉产区JaVC的发生及变异情况分析,为JaVC引起的病毒病的防治提供了理论依据。     

Macrophages largely contribute to heterologous anti‐Propionibacterium acnes antibody‐mediated protection from Actinobacillus pleuropneumoniae infection in mice

Actinobacillus pleuropneumoniae is the causative agent of acute and chronic pleuropneumonia. Propionibacterium acnes is a facultative anaerobic gram‐positive corynebacterium. We have previously found that anti‐P. acnes antibodies can prevent A. pleuropneumoniae infections in mice. To investigate the role of macrophages in this process, affinity‐purified anti‐P. acnes IgG and anti‐A. pleuropneumoniae IgG were used in opsonophagocytosis assays. Additionally, the efficacy of passive immunization with P. acnes serum against A. pleuropneumoniae was tested in macrophage‐depleted mice. It was found that anti‐P. acnes IgG had an effect similar to that of anti‐A. pleuropneumoniae IgG (P > 0.05), which significantly promotes phagocytosis of A. pleuropneumoniae by macrophages (P < 0.01). It was also demonstrated that, after passive immunization with anti‐P. acnes serum, macrophage‐replete mice had the highest survival rate (90%), whereas the survival rate of macrophage‐depleted mice was only 40% (P < 0.05). However, macrophage‐depleted mice that had been passively immunized with naïve serum had the lowest survival rate (20%), this rate being lower than that of macrophage‐replete mice that had been passively immunized with naïve serum. Overall, anti‐P. acnes antibodies did not prevent A. pleuropneumoniae infection under conditions of macrophage depletion (P > 0.05). Furthermore, in mice that had been passively immunized with anti‐P. acnes serum, macrophage depletion resulted in a greater A. pleuropneumoniae burden and more severe pathological features of pneumonia in lung tissues than occurred in macrophage‐replete mice. It was concluded that macrophages are essential for the process by which anti‐P. acnes antibody prevents A. pleuropneumoniae infection in mice.     

LysGH15 reduces the inflammation caused by lethal methicillin-resistant Staphylococcus aureus infection in mice

The endolysin LysGH15, derived from staphylococcal phage GH15, has a wide lytic spectrum and strong lytic activity against Staphylococcus aureus, especially methicillin-resistant S. aureus (MRSA), in vitro and in vivo. Here, the ability of lethal MRSA to induce mRNA levels of interleukin-6 (IL-6), interleukin-4 (IL-4), and interferon-γ (IFN-γ) in spleen tissues of mice was studied. A large number of bacteria were detected in spleens. The bacteria caused elevated expression levels of these three cytokines. Administration of LysGH15 significantly reduced the number of bacteria and the levels of IL-6, IL-4, and IFN-γ mRNA in spleen cells compared with those in untreated mice at 24 h (P < 0.05). LysGH15 can eliminate a large number of bacteria and effectively alleviate inflammation induced by infection with lethal MRSA.