Figures
Abstract
Mycobacterium abscessus subsp. massiliense, a rapidly growing mycobacteria (RGM) that is becoming increasingly important among human infectious diseases, is virulent and pathogenic and presents intrinsic resistance to several antimicrobial drugs that might hamper their elimination. Therefore, the identification of new drugs to improve the current treatment or lower the risk of inducing resistance is urgently needed. Wasp venom primarily comprises peptides that are responsible for most of the biological activities in this poison. Here, a novel peptide Polydim-I, from Polybia dimorpha Neotropical wasp, was explored as an antimycobacterial agent. Polydim-I provoked cell wall disruption and exhibited non-cytotoxicity towards mammalian cells. Polydim-I treatment of macrophages infected with different M. abscessus subsp. massiliense strains reduced 40 to 50% of the bacterial load. Additionally, the Polydim-I treatment of highly susceptible mice intravenously infected with M. abscessus subsp. massiliense induced 0.8 to 1 log reduction of the bacterial load in the lungs, spleen, and liver. In conclusion, this is the first study to show the therapeutic potential of a peptide derived from wasp venom in treating mycobacteria infections. Polydim-I acts on the M. abscessus subsp. massiliense cell wall and reduce 40–90% of the bacterial load both in vitro and in vivo. The presented results encourage further studies on the use of Polydim-I as one of the components for M. abscessus subsp. massiliense treatment.
Citation: das Neves RC, Trentini MM, de Castro e Silva J, Simon KS, Bocca AL, Silva LP, et al. (2016) Antimycobacterial Activity of a New Peptide Polydim-I Isolated from Neotropical Social Wasp Polybia dimorpha. PLoS ONE 11(3): e0149729. https://doi.org/10.1371/journal.pone.0149729
Editor: Bernhard Ryffel, French National Centre for Scientific Research, FRANCE
Received: November 20, 2015; Accepted: February 4, 2016; Published: March 1, 2016
Copyright: © 2016 das Neves et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting information files.
Funding: This work was financially supported through a grant from the CNPq-Rede Pró-Centro-Oeste de Pesquisa (n0: 564243/2010-8) and MCT/CNPq/FNDCT/FAPEG/MEC/CAPES/Pro-Centro-Oeste 031/2010 (n0: 201110267000106). The funding agency had no involvement in the study design, data collection, and data analysis or in the decision to submit this manuscript for publication.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Mycobacterium abscessus subsp. massiliense is a rapid growing mycobacteria (RGM) that is becoming increasingly important among human infectious diseases and is associated with soft tissue infections that are caused by contaminated hospital equipment and solutions following small invasive procedures or intramuscular injections [1, 2]. This group includes the formally known Mycobacterium massiliense [3, 4] that is virulent and pathogenic, inducing a chronic and disseminated evolution in the host, independent of the immune status [3–7]. In Brazil, 2,000 new cases of RGM infections have been diagnosed since 1998, most of which occurred following surgical procedures such as myopia correction, mesotherapic procedures, breast implants, or esthetical procedures, usually associated with contaminated videoscopy equipment and solutions. Among the RGM detected, most of these cases were infections with M. abscessus subsp. massiliense [8, 9].
M. abscessus subsp. massiliense infection outbreaks might be a consequence of the intrinsic resistance of these bacteria to 2% glutaraldehyde, a commonly used high-level disinfecting solution [2]. The most appropriate treatment for M. abscessus subsp. massiliense infections is to use a combination of drugs to avoid the development of resistance. Currently, the most commonly used chemotherapy includes the use of clarithromycin (CLR) together with amikacin (AMK) [5], moxifloxacin (MXF) or cefoxitin (FOX) [6]. The major problem of chemotherapy, in addition to intrinsic resistance, is the development of resistant strains that vary from 4.5% resistance to CLR to 18% to FOX [10]. In addition, these drugs have hepatotoxic, enterotoxic, nephrotoxic, hematotoxic and skin side effects when used for long periods of time, and these side effects may result in non-adherence to therapy [11]. Consequently, new, improved and efficient drugs against RGM are essential.
An interesting approach for the development of new drugs is the use of antimicrobial peptides (AMP), also known as natural antibiotics. Interestingly, AMP can be administered individually or in association with conventional chemotherapeutic drugs and have presented promising results for treating several infectious diseases [12–14]. The mechanisms underlying the activity of AMP actions seem to vary according to each family of molecules, but in general, these activities rely on their ability to permeabilize biological membranes, create pores, or affect intracellular activities [15].
Wasp venoms primarily comprise peptides, including AMP, which are responsible for most of the biological activities of this poison. Among those peptides, the most recurrent are those from the class of mastoparans [16–18], small cationic and amphiphilic alpha-helical peptides that possess high affinity to negatively charged biological membranes. Thus, the venom of social wasps has great potential for the study of new antimicrobials, particularly with respect to antimycobacterial activity. Currently, countless peptides remain unknown because of a lack of studies focusing on the identification of antimicrobial peptides from the venom of Neotropical social wasps. Thus, the aim of this study was to investigate the effects of a novel peptide: Polydim-I that was isolated from the venom of the Neotropical wasp Polybia dimorpha as a potential antimycobacterial agent.
Materials and Methods
Collection of specimens and venom extraction
Females of Polybia dimorpha were collected at Brasília, Distrito Federal, Brazil, under license in accordance with the Normative Instruction No. 154, from March 2007, of IBAMA (Brazilian Institute of Environment and Renewable Natural Resources, license number 21723–1). Moreover, authorization of the Access and Remittance of the Brazilian genetic patrimony was obtained from the CNPq (license number 010476/2013-0). The wasps were sacrificed after freezing at -20°C. Following species identification (Prof. Fernando B. Noll, UNESP-SP), the venom sacs were dissected and macerated in a 10% acetonitrile in deionized water solution and centrifuged at 5000 × g for 10 min, at 4°C. The supernatant was carefully collected and submitted to a filtration using an ultra-filter (Millipore) with a 3-kDa cut-off for 30 min at 5000 × g. The resultant ultrafiltrate, which was characterized by the presence of low molecular mass compounds, was collected, lyophilized and weighed.
Peptide fractionation and purification
The filtered extract was resuspended in 2% acetonitrile in water (ACN/H2O) and 0.07% trifluoroacetic acid (TFA). The solution was subjected to chromatography using a reversed-phase high performance liquid chromatography (RP-HPLC) column (C18 ODS, Jupiter 15 μm, 20 × 250 mm, Phenomenex, Torrence, CA, USA) at a flow rate of 1.5 mL/min and was then eluted using a linear gradient from 5% ACN/H2O (v/v) (containing 0.07% TFA) for 20 min, followed by 5 to 60% for 40 min and under 60% for 20 min. The absorbance of the eluted compounds was monitored at 214 and 280 nm, and the fractions were manually collected and subsequently lyophilized.
MALDI-TOF mass spectrometry
The fractions containing Polydim-I were subjected to identification (purity and identity) through matrix-assisted laser desorption/ionization mass spectrometry time-of flight (MALDI-TOF TOF) (UltraFlex III, Bruker Daltonics, Germany) under reflector (MS) and LIFTTM (MS/MS) positive modes. Prior to analysis, the fractions were dissolved in a saturated solution of α-cyano-4-hydroxycinnamic acid matrix in acetonitrile/water/3% trifluoroacetic acid (5/4/1). Additionally, the peptides’ mass spectra and sequencing were manually interpreted using the FlexAnalysis 3.0 software (Bruker Daltonics, Germany). The monoisotopic molecular mass of the peptide was determined as the ratio between the m/z peaks in the spread profile (m/z ratio from 600 to 3,000). Moreover, similarity searches were performed using Fasta3 programs, the Expasy12 server and BLASTP13.
Polydim-I synthesis
The Polydim-I (a novel peptide derived from wasp Polybia dimorpha venon) was synthesized through solid phase chromatography using an N-9-fluorophenylmethoxy-carbonyl (F-MOC) strategy and purified through RP-HPLC at Aminotech Development and Technology. Moreover, the purity and sequence of the peptide were assessed using the same protocol described for the identification of the natural peptide.
Bacterial strain preparation
M. abscessus subsp. massiliense isolates GO 01, GO 06, GO 07, GO 08, GO 13, and GO 18, were randomly chosen from a collection bank of isolates from a Brazilian epidemic outbreak that occurred in Goiânia, State of Goiás during 2005 and 2007 [5], and CRM0020 (M. abscessus subsp. massiliense), and ATCC19977 (M. abscessus subsp. abscessus) reference strains were included. M. abscessus subsp. massiliense were identified previously by colony morphology, biochemical testes, PCR-Restriction-enzyme Analysis (PRA-hsp65), and partial rpoB gene sequencing [5]. For the in vitro experiments, aliquots of frozen mycobacteria were grown in Mueller Hinton (MH, HIMEDIA) with 0.05% Tween 80 at 35°C with agitation (200 × rpm) for three days. The culture concentration was adjusted to a 0.5 scale of McFarland (approximately 1.5 × 108 CFU/mL) after vigorous homogenization to dissolve clumps.
For mice intravenous injection, M. abscessus subsp. massiliense GO 06, previously evaluated in mice [19] with known concentration and maintained at -80°C were thawed and suspended in phosphate-buffered saline (PBS), 0.05% Tween 80 to approximately 106 CFU/mL.
All M. abscessus subsp. massiliense suspensions were plated onto MH agar for CFU determination.
Minimum inhibitory concentration test (MIC)
MIC was determined according to ATS/IDSA recommendations [20]. Bacterial cultures were further adjusted, and 100 CFU was deposited into each well of a 96-well microplate that contained serially diluted Polydim-I in levels ranging from 243.2 to 3.8 μg/ml. Lyophilized Polydim-I was resuspended in 3% DMSO and further diluted in PBS before adding to the cultures. The control wells received bacteria and PBS (growth control) or CLR at concentrations ranging from 8 to 0.06 μg/mL (inhibition control). The plates were incubated for three days at 35°C. The MIC (lowest concentration without bacterial growth) was estimated by CFU counting after plating in MH media.
Scanning Electron Microscopy analysis of peptide effect on M. abscessus subsp. massiliense
M. abscessus subsp. massiliense colonies grown on MH agar were removed from the plates and exposed to 3.8 or 7.6 μg/mL of Polydim-I or 0.5 μg/mL of clarithromycin for 24 h. As a negative control, the colonies were incubated with PBS alone. After incubation, the cells were fixed with modified Karnovsky solution (paraformaldehyde 1% and glutaraldehyde 3% in 0.07 M cacodylate buffer, pH 7.2) for 30 min at 4°C. The fixative solution was subsequently removed, and the samples were dehydrated through increasing concentrations of ethanol solution (30%, 50%, 70%, 90%, and 100%) for 10 min, followed by acetone and hexamethyldisilazane (HMDS) (V/V) for an additional 5 min. The final dehydration step was performed with HMDS for 5 min. After the samples were completely dry, a thin layer of gold was deposited using a Denton Vacuum Desk V apparatus. The images were obtained using a Jeol JSM – 6610 microscope (Jeol, Japan) equipped with energy dispersive spectroscopy—EDS (Thermo scientific NSS Spectral Imaging).
Animals
BALB/c and IFN-γKO (Knockout) mice were obtained from the Instituto de Patologia Tropical e Saúde Pública from Federal University of Goiás animal facilities. All animals were housed according to the Colegio Brasileiro de experimentação animal (COBEA) under the supervision of a Veterinarian. Female mice that were 6–8 weeks old and weighed 22–25 g from both lineages were used. Five groups of 6 animals (IFN-γKO) each were maintained in a HEPA filtered rack with water and food available ad libitum. To enrich the animal environment, cardboard tubes were weekly added to the cages for the 28–30 days duration of the study. Ten BALB/c mice that were maintained under the same conditions were used to obtain macrophages. All protocols were submitted and approved through the Comitê de Ética no Uso de Animais em Pesquisa-UFG (Protocol: 027/14). All experiments were repeated three times, and a total of 10 BALB/c and 90 IFN-γKO mice were used.
Peritoneal macrophages cultures
BALB/c mice were injected with thioglycolate 72h before the peritoneal macrophages were collected. The macrophages (1 × 106 cells/ml), which were diluted in RPMI-1640 (Sigma, St. Louis, USA) supplemented with penicillin/streptomycin (100 U/mL, 100 g/mL), 2 mM L-glutamine, 2 mM non-essential amino acids, 1 mM sodium pyruvate (all reagents from Sigma-Aldrich, St Louis, MO, USA) and 10% fetal bovine serum (FBS), were incubated for 24 h at 37°C, 5% CO2, in 24-well microplates containing 18-mm circular cover slides or in 96 well microplates. Peritoneal macrophages plated in 24-well microplate were used to evaluate the morphology/viability after Polydim-I treatment of infected macrophages. The peritoneal macrophages plated in 96 wells plates were used to address the microbicidal effects of Polydim-I on infected macrophages (see details bellow).
J774 macrophage cytotoxicity evaluation
Cytotoxic activity was measured using J774 macrophages cells treated with 7.6, 15.2, 60.8, and 121.6 μg/mL of the peptide for 24 h under the same conditions as described for peritoneal macrophages. The percentage of cytotoxicity of Polydim-I was evaluated by lactate dehydrogenase (LDH) release assay using Cyto Tox 96 kit (Promega).
Hemolysis
A solution of fresh human red blood cells was used to test the hemolytic capacity of the peptide at levels ranging from 7.6 to 121.6 μg/mL. Fifty micro liters of a 3% cell suspension of EDTA treated blood obtained from healthy volunteers were added to a 96 well microplate. Different concentrations of the peptide (v/v) were added to each well and after one hour incubation, the microplates were centrifuged, and the supernatant was carefully collected and read at 540 nm using an ELISA microplate reader (Thermo Labsystems, USA). As positive lysis control the erythrocytes were incubated with water. The percentage of hemolysis from each test was calculated relative to the positive control. Blood were collected from healthy individuals that signed a written Informed Consent. The procedures and the informed consent were approved by the Ethics Committe on Human Research of Faculty of Medicine/University of Brasilia (UNB).
Mycobactericidal activity of Polydim-I on infected macrophages
Peritoneal macrophages that were obtained as described above were infected with M. abscessus subsp. massiliense (MOI 10:1) for three hours. Subsequently, the cultures were washed three times with warm RPMI. The obtained supernatants from the washes were pooled and plated onto MH agar for CFU determination. The infected macrophages were treated with Polydim-I at 7.6 μg/mL in 200 μL of RPMI. After three days of incubation, the supernatant was removed, the cells were washed three times with warm PBS to remove extra cellular bacteria and the cells were lysed with water. The resulting lysate and supernatant were spread onto MH agar for CFU determination. To estimate the number of bacteria phagocytosed by macrophages prior to Polydim-I treatment, the number of CFU obtained from the pooled supernatant after three hours of infection was subtracted from the total inoculum (106). Additionally, infected peritoneal macrophages were cultivated in 24 well plate containing circular cover slides to investigate the cell morphology. Three independent experiments were performed. Additionally, two experiments were performed using non-activated peritoneal macrophages to confirm Polydim-I bactericidal activity.
The cover slides from the 24-well microplates were washed with PBS and fixed with methanol for 5 min. Then, the slides were stained with Instant Prov (Newprov, Pinhais, Brazil) and attached to glass slides using Entellan (Merck, Darmstadt, Germany), and photomicrographs (400 ×) were captured using light microscopy (Carl Zeiss, Oberkochen, Germany).
Infection of IFN-γKO mice with M. abscessus subsp. massiliense
The animals were intraperitoneously anaesthetized with a mixture of 70mg/kg of ketamine and 7mg/kg of xylazine followed by intravenous infection in the retro-orbital plexus with 106 CFU of M. abscessus subsp. massiliense GO 06. The bacteria load in the mice organs was monitored at days 1 and 18 post infection. At day one post infection, one animal from each treatment group (total of 6 animals) was euthanized to determine the efficiency of the infection. The animals were routinely (twice daily) inspected for mortality during 18 days. Animal health was monitored for the following signs: loss of appetite, dehydration, prostration or lethargy. A humane endpoint protocol to perform euthanasia of animals presenting any of the above symptoms was approved the Ethical Committee on the animal use of Universidade Federal of Goiás. None of the animals presented any of the above signs or died during the experiments. Eighteen days after infection, the lungs, liver and spleen from one animal of each treatment group were homogenized in PBS containing 0.05% of Tween 80, and the bacterial load of the organs was determined as previously described [19]. Briefly, the lungs, liver and spleen were homogenized in 5 mL of PBS with 0.05% of Tween 80. The organ homogenates were serially diluted in PBS/Tween 80, plated onto MH agar plates and incubated for 7 days at 35°C. The colonies grown on MH agar plates were counted, and the bacterial load in each organ was determined after correcting the values based on dilution, plating volume, and the volume of homogenates.
Treatment of IFN-γKO mice infected with M. abscessus subsp. massiliense
The Polydim-I treatment scheme for M. abscessus subsp. massiliense was performed according to [21] with some modifications. Briefly, anesthetized IFN-γKO mice were intravenously infected with M. abscessus subsp. massiliense (106 CFU/mL). Prior to treatment, the animals were individually weighed, and the mean live weight (mLW) was used to calculate the treatment dose. After 18 days of infection, the animals (4 animals/group) were treated once a day intraperitoneally for eight days. During the treatment, the animals were monitored for signs of sickness as state above. For the Polydim-I treatment, three groups received the following dose treatments: 2 mg/kg/mLW, 1 mg/kg/mLW, and 0.5 mg/kg/mLW [2, 22]. As controls, a group was treated with CLR (200 mg/kg/mLW, treatment control) and another group received PBS (infection control). None of the animals became clinically ill or died during the experiments. To minimize pain and distress the animals were quickly handled by trained researchers. All animals were humanely euthanized by cervical dislocation by a veterinarian, one day after the end of the treatments, and the spleen, lungs and liver were collected separately and frozen for CFU determination. The experiments were repeated three times.
Histopathological analysis
Twenty six days after intravenous infection, the right caudal lung lobes were removed and fixed in 10% buffered formaldehyde. To evaluate in vivo acute cytotoxicity effect of Polydim I, BALB/c mice treated with 2 or 20 mg/kg/mLW and the livers were analyzed 48 hours later. Five micrometers thick slices were stained with Hematoxilin and Eosin (H.E.) and analyzed with light microscopy (Leica DM/LS IV 500 microscopy system), and images were processed with LAS software version 4.4 (Leica). A certified Pathologist blinded to original section sources evaluated the slides. Scores were determined based on the area with lesions relative to the area of the total visual field using AxioVision microscopy Software. The results are presented as the percentage of area with lesions. Three different fields were evaluated per slide for each animal from each group.
Statistical analysis
The experimental data were tabulated and grouped using the Microsoft Excel 2010 software and exported to the Graph Pad Prism 5.0 software (Graph Pad Software, San Diego CA, USA) for statistical analysis. The results were compared using one-way ANOVA, followed by Dunn’s test. p-values less than 0.05 were considered statistically significant. Data are available as online files (S1–S4 Figs).
Results
Separation, identification and synthesis of Polydim-I
A total of 684 venom glands were obtained from a single nest of Polybia dimorpha and provided 21.4 mg of ultrafiltered crude venom (compounds with molecular masses lower than 3,000 Da). The obtained RP-HPLC profile comprised 13 fractions (Fig 1A), which were termed Poly 1–13. Two chromatographic procedures with injections of 200 μL each were performed, and both profiles showed the same fraction elution pattern. Polydim-I corresponded to fraction Poly 12, eluted at a retention time of approximately 62 min at 60% of ACN as indicated in Fig 1A.
(A). Chromatographic profile obtained after separation of the low molecular weight compounds from Polybia dimorpha venom through reversed phase high performance liquid chromatography. The fraction containing the peptide Polydim-I is signalized. (B) Mass spectra of fraction 12 obtained through MALDI TOF/TOF, with the major ion m/z 2441.7 [M+H]+. (C). De novo sequencing of Polydim-I using MS/MS. The ion series y is written above with the 22 amino acids represented by letters.
Fraction 12 had a major molecular component at m/z 2441.7 [M+H]+ based on the mass spectrometry analysis, and this peptide was named Polydim-I (Fig 1B). De novo sequencing of the fragmented ion through MS/MS resulted in a sequence of 22 amino acid residues (AVAGEKLWLLPHLLKMLLTPTP), as shown in Fig 1C.
Thus, Polydim-I was synthesized at Aminotech Development and Technology LTDA. The purity (> 99%) and the correct sequence of the peptide were verified and confirmed through mass spectrometry upon receipt using the same parameters that were used for the natural compound.
In vitro antimycobacterial and morphology modification activities of Polydim-I against M. abscessus subsp. massiliense
The Polydim-I antimycobacterial activity was evaluated against six isolates of M. abscessus subsp. massiliense from an epidemic outbreak and two reference strains resulting in a MIC of 60.8 μg/mL, while treatment at a concentration of 15.2 μg/mL inhibited 55 to 68% of M. abscessus subsp. massiliense strains growth (data not shown). To determine whether the mycobactericidal effect of Polydim-I could influence the shape of the cell envelope, scanning electron microscopy (SEM) of M. abscessus subsp. massiliense GO 06 exposed to the peptide was performed. As shown in Fig 2, the cellular shape and cell wall integrity were slightly affected when the mycobacteria were exposed to 7.6 μg/mL of the peptide (Fig 2B, arrow heads). The cell shape was expressively damaged when the concentration of the peptide was 15.2 μg/mL (a representative damaged area is shown in Fig 2C). The exposure of M. abscessus subsp. massiliense to the antibiotic CLR, which prevents bacterial growth through the inhibition of protein synthesis, did not result in visible morphological changes (Fig 2D). Taken together, the SEM data suggest that Polydim-I might elicit deleterious effects through perturbations of the cell integrity.
(A) Scanning Electron microscopy of untreated M. abscessus subsp. massiliense cells. (B) M. abscessus subsp. massiliense exposed to 3.8 μg/mL of Polydim-I peptide for 24 hours, presenting mild surface alterations (white arrows). M. abscessus subsp. massiliense with severe cell wall disruptions after treatment with 7.6 μg/mL of Polydim-I peptide for 24 hours (C). (D) M. abscessus subsp. massiliense treated with clarithromycin (0.5 μg/mL) without visible cell wall damage. (A) and (C) 10,000 × magnification. (B) and (D) 12,000 × magnification.
Polydim-I displays bactericidal activity on intracellular environment
To further investigate whether a combination of mycobacteria infection and peptide treatment could affect the membrane integrity of peritoneal macrophages, these cells were infected with six different M. abscessus subsp. massiliense isolates or the reference strains CRM0020 and ATCC19977 (at MOI 10:1) and treated with 7.6 μg/mL of Polydim-I. All tested strains behaved similarly, and as shown in S5A Fig (control) and S5B (treated), the peptide treatment of peritoneal macrophages apparently did not affect the cell morphology, which was not altered after infection with the representative M. abscessus subsp. massiliense isolate GO 06 shown in S5C and S5D Fig. The macrophage morphology suggests that they were viable throughout the experiments. Additionally, CFU counting of infected and Polydim-I treated macrophages showed a significant reduction in the bacterial load when compared to the infected non-treated macrophages (40 to 50% range; Figs 3 and 4). Infected macrophages treated with 1μg/ml of CLR reduced 57–70% the bacterial load among the different tested strains (Fig 4).
Peritoneal macrophages from BALB/c mice were infected with 6 isolates of M. abscessus subsp. massiliense (A thru F) or the reference strains CRM0020 (G) and ATCC19977 (H) at a MOI of 10:1, and treated with 7.6 μg/mL of Polydim-I peptide or with 1 μg/mL of clarithromycin. Bacterial load of phagocytosed bacteria were determined at three hours after infection and total recovered bacteria from supernatant and macrophages at 72 hours after infection were determined for non-treated (closed circles), peptide treated (closed squares), and clarithromycin treated (open circles). The data represent mean of quadruplicates and is representative of three independent experiments. One-way ANOVA followed by Dunn’s test was used to determine significant differences (* p<0.05).
The CFU in peritoneal macrophages, 72 hours after treatment with Polydim-I (white bars) or clarithromycin (black bars), was determined and the percentage of inhibition was calculated in relation to non-treated macrophage cultures. The data represent mean of quadruplicates and is representative of three independent experiments. One-way ANOVA followed by Dunn’s test was used to determine significant differences (* p<0.05).
As reasoned above, Polydim-I activity might be associated with the disruption of cell membrane integrity. Nonetheless, to be a potential candidate as an antimicrobial agent, this compound must show selective toxicity (12). Consequently, we analyzed whether Polydim-I interferes with eukaryotic cell membranes using J774 macrophage cell line treated with 7.6, 15.2, 60.8, and 121.6 μg/mL of Polydim-I for 24 hours using LDH release assay. Polydim-I started to present cytotoxicity on J774 cells at concentrations above 121.6 μg/mL (10%) (Fig 5A). However the Polydim-I peptide at concentrations up to 121.6 μg/mL presented less than 2.5% of hemolytic activity (Fig 5B).
J774 macrophages were exposed to different concentrations of Polydim-I peptide (7.6, 15.2, 60.8, or 121.6 μg/mL) for 3 days. Cell viability percentage was determined by LDH release assay (A). In (B), the percentage of human red blood cells lysis. The results represent three independent experiments.
In vivo anti-mycobacterial activity of Polydim-I
We have previously shown that BALB/c or C57BL/6 intravenous infection with M. abscessus subsp. massiliense strain GO 06 (106 CFU) provided an adequate model of infection with the bacterial load maintained until 30 days post infection [19]. To optimize the analysis of the peptide treatment effect in vivo, IFN-γKO mice, that have increased susceptibility to mycobacterial infection, were infected with M. abscessus subsp. massiliense. Eighteen days post infection, these animals were treated for 8 days with CLR (200 mg/kg/mLW) or one of three different doses of Polydim-I (2, 1 or 0.5 mg/kg/mLW) for 8 days. Fig 6 shows the CFU obtained after 28 days post infection with M. abscessus subsp. massiliense and the different treatment schemes. As shown, Polydim-I treatment at 2 mg/kg/mLW showed significant reduction of the bacterial load in all analyzed organs. The peptide treatment at this concentration reduced the bacillary load of the susceptible animals by up to 90% in the lungs and spleen (Fig 7). In addition, Polydim-I treatment of mice infected with M. abscessus subsp. massiliense reduced the inflammatory response caused by the infection as determined by the quantification of the area occupied by lesion/inflammatory responses (Fig 8). The highest dose of Polydim-I used to treat infected mice did not show damages associated with cytotoxicity in the lungs or liver (Data not shown and S6 Fig).
IFN-γKO mice were infected intravenously with 106 CFU of M. abscessus subsp. massiliense strain GO 06. Eighteen days after infection, the mice were treated with 2 mg/kg/mLW of Polydim-I (▲), 1 mg/kg/mLW of Polydim-I (▼), 0.5 mg/kg/mLW (■) of Polydim-I, or with 200 mg/kg/mLW of clarithromycin (CLR, ○). As control, a group of infected mice were treated with PBS (●). The bacillary loads in the lungs (A), spleen (B) and liver (C) were determined after euthanizing the mice at days 1, 18 and 26 post infection. The data represent mean of four mice per group and is representative of three independent experiments. One-way ANOVA followed by Dunn’s test was used to determine significant differences. Statistically significant difference when compared to PBS treated control group (* p<0.05).
IFN-γKO mice were infected intravenously with 106 CFU of M. abscessus subsp. massiliense. Eighteen days after infection, the mice were treated with Polydim-I peptide at three different dosages (2, 1 or 0.5 mg/kg/mLW) or with clarithromycin (CLR 200 mg/kg/mLW). As a control group, infected mice were treated with PBS. Percentages of bacterial load reduction in the lungs (A), spleen (B) and liver (C) from each treatment group were determined relative to the control PBS group (* p<0.05).
Twenty-six days after the challenge, the lungs were processed, sectioned, HE stained, and examined at 40 × or 100 × magnification. (A and B) normal lungs from PBS treated control group at 40 × and 100 × magnifications, respectively; inflammatory lesions observed in the lungs of the infected group 40 × (C) and 100 × (D). Lungs from animals infected and treated with Polydim-I (2 mg/kg/mLW) 40 × (E) and 100 × (F). The area of the inflammatory lesions were calculated and plotted in a graph (G). One-way ANOVA followed by Dunn’s test was used to determine significant differences (* p<0.05).
Discussion
M. abscessus subsp. massiliense presents resistance to several of the conventional treatment regimens that are typically used to treat M. tuberculosis. Therefore, the identification of new drugs to improve the current treatment or lower the risk of inducing resistance is urgently needed. In this context, the present work shows the first use of a peptide derived from wasp venom that possesses mycobactericidal activity. Polydim-I provoked cell wall disruption and presented low cytotoxicity towards mammalian cells. The treatment of M. abscessus subsp. massiliense-infected macrophages with the peptide reduced approximately 50% of the bacterial load. Additionally, Polydim-I treatment of highly susceptible mice infected with M. abscessus subsp. massiliense induced a reduction of the bacterial load in the lungs, spleen, and livers.
Polydim-I, which was a peptide, isolated from the venom of Polybia dimorpha, presents characteristics similar to other wasp AMPs (Fig 1), with a structure comprising a series of hydrophobic amino acid residues, such as methionine, leucine, valine, and proline, which are intercalated with negatively charged residues to create an amphipathic surface [23, 24]. However, due to the intrinsic characteristics observed in the sequence of this peptide, it cannot be classified as mastoparan and has subsequently emerged as a new class of peptides within the major group of AMPs. Some peptides isolated from other wasps, such as MP-AF and MPI, exhibit interesting antimicrobial activity against Gram-positive and Gram-negative bacteria [25] as well as antifungal activity against Candida albicans and Candida glabrata yeasts [26]. Natural peptides, such as RR-11, a cationic host defensin, have been demonstrated to have activity against M. smegmatis [27] when used at a concentration of 125 μg/mL. Our findings are promising, as using a much lower concentration of peptide (7.6 μg/mL) achieved a 50% reduction of mycobacterial growth. Although we have included in our experiments Tween 80 to avoid clumping, a factor that has been shown to disrupt mycobacteria cell wall integrity before [28], we believe that that inhibitory effect is mainly due to the peptide because all controls also were grown with the detergent.
The treatment of M. abscessus subsp. massiliense with Polydim-I disrupted the bacteria cell envelope (Fig 2); a similar phenomenon was observed when Candida sp. [26] were treated with the wasp MPI peptide, which caused cell wall disruptions. Defensin RR-11 also promoted M. smegmatis cell wall destruction [29]. LL-37, a cathelicidin that is secreted from macrophages, exhibited anti-mycobacterial activity, further strengthening the potential use of these agents against mycobacteria [30]. In a recent review, Padhi and colleagues suggested that the mechanism of action of natural peptides showing activity against mycobacteria involves the destruction of cell envelope structures and/or functions through associations with lipoarabinomannan [30, 31]. Additionally, bacterial membranes have unique lipids such as phosphatidylglycerol, cardiolipin or phosphatidelserine conferring a negative charge that may favor AMP association [25]. Thus, the activity of Polydim-I is likely associated with cell envelope or cell wall damage because this effect was primarily observed with other microorganisms [25, 26], but further studies in this field are needed.
Macrophages are the main targets of mycobacteria and are morphologically and functionally well characterized; hence, these cells were used in cytotoxicity assays (J774 macrophages) and to evaluate in vitro Polydim-I action against M. abscessus subsp. massiliense phagocytosed by macrophages. The membrane and cell envelope interference properties of natural peptides could affect eukaryotic cells [32], but the peptide used in the present study did not exhibit any expressive interaction or destruction of eukaryotic cell membranes at concentrations ≤60.8 μg/mL. Natural peptides such as cathelicidin also presented selective toxicity to mycobacteria without damaging macrophage membranes [33], and this might be associated with the cholesterol and other lipid contents of eukaryotic membranes [31]. In addition, cationic AMPs interact with negatively charged membranes, such as seen among bacteria and tumoral cells [34, 35] forming pores, a role most likely performed by the arginine amino acid residues present in the peptides [34]. In contrast, the membranes of normal eukaryotic cells have a predominant neutral charge and consequently could be resistant to the AMPs action. The results of our research describes for the first time, a peptide isolated from the venom of wasps with activity against mycobacteria and although it presented some in vitro cytotoxicity, it can be further modified to improve its efficacy (reduce cytotoxicity and increase mycobactericidal activity). The in vivo selective action presented by Polydim-I could be due to the presence of two arginine residues present in its N-terminus. These results are promising because for other wasp AMPs, particularly mastoparans such as MP-AF, MP-A, MP-B, MP-D, MP-M, and MP-V, high cell toxicity through hemolysis was observed [24]; however, the results obtained in the present study showed a low level of hemolysis.
Treatment of infected macrophages with 7.6 μg/mL of Polydim-I decreased approximately 50% of the bacterial load. Although few studies have used infected macrophages to test new drugs against mycobacteria [36], no scientific publication, to our knowledge, has examined new drugs using macrophages that were infected with M. abscessus subsp. massiliensi, previously known as M. massiliense [4]. We hypothesize that an efficient drug will need to penetrate granuloma and should not be eliminated through efflux pumps [37] in order to eliminate the mycobacteria within the infected macrophages [36]. Therefore, infected macrophages are also an effective model to evaluate the mechanism of action of antimycobacterial drugs.
Because this is the first study evaluating the treatment of mice infected with M. abscessus subsp. massiliense, we used the mouse model of Lenaerts and colleagues [21] to test drugs against M. tuberculosis. IFN-γKO mice are highly susceptible to mycobacteria infections [38], particularly infections with M. abscessus subsp. massiliense [7], which facilitates a more rapid treatment result. Additionally, we used parenteral drug treatments in order to guarantee homogeneous bioavailability for all drugs as proposed before [22, 23]. The treatment of IFN-γKO mice infected with M. abscessus subsp. massiliense using 2 mg/kg/mLW of Polydim-I substantially reduced the bacterial load in the lungs, spleen and livers (Figs 6 and 7). Importantly, when clarithromycin was used, the M. abscessus subsp. massiliense was not cleared from IFN-γKO-infected mice; this finding indicates that, as observed with human RGM infection, a multidrug therapy is always needed to avoid bacterial persistence and possibly drug resistance development [39, 40]. The results obtained in the present study are consistent with those obtained for several drugs that have been demonstrated as useful for treating mycobacterial infections [36, 41]. It will be interesting to evaluate the effect of Polydim-I treatment combined with other drugs.
Lungs from animals infected with M. abscessus subsp. massiliense and treated with Polydim-I showed less inflammatory lesions than the lungs from infected animals. Although, no work have used IFNγ-KO to test new drugs to treat M. abscessus subsp. massiliense infection, others have shown that depending on the peptide used, the bacterial load reduction is accompanied or not by reduction of the inflammatory lesions induced by M. tuberculosis infection [29, 42]. It is interesting to note that the treatment with Polydim-I using doses ranging from 10 to 40 μg per animal, doses bellow the MIC, were sufficient to reduce approximately one Log of the bacterial burden. Other authors have shown that AMP activate macrophages enhancing their bactericidal activity as well as cytokine production [14, 43, 44]. Here we hypothesize that Polydim-I might activate the infected macrophages potentiating the mycobacteria clearance.
M. abscessus subsp. massiliense is susceptible to parenteral drugs (amikacin, cefoxitin, and imipenem) and oral macrolides (clarithromycin and azithromycin). Consequently, the ATS/IDSA (American Thoracic Society/Infectious Disease Society of America) recommends that at least two parental drugs and one oral drug should be used to treat infections to avoid drug resistance development [20]. These drugs cause several collateral effects, such as gastric intestinal dysfunction, ototoxicity, and neurotoxicity [45], and the use of clarithromycin has been associated with a significantly increased risk of cardiac death [46]. Novel drugs, which target different structures compared with most of the commercially available drugs, could be incorporated into multi-regimen treatments, thereby reducing the dosage and/or number of drugs used and consequently lowering the risk of developing side effects. Therefore, Polydim-I could improve the treatment of M. abscessus subsp. massiliense infections because of the lower risk of resistance development and the lower cost of production.
Some important aspects about the use of AMPs in general should be pointed out as for example they could be degraded faster than other anti-microbial agents due to the action of tissue peptidases/proteinases in vivo. Additionally, peptides could combine to host proteins and generate specific humoral immune responses that could impair repetitive use of the peptide [47–49].
In conclusion, this study was the first to demonstrate the therapeutic potential of a peptide derived from wasp venom to treat mycobacteria infections. Polydim-I acts on the M. abscessus subsp. massiliense cell wall and reduced the bacterial load both in vitro and in vivo. These results encourage further studies on the use of Polydim-I and its derivative peptides as a component in the M. abscessus subsp. massiliense infection treatment formulation.
Supporting Information
S1 Fig. MIC determination raw data experiment.
https://doi.org/10.1371/journal.pone.0149729.s001
(PDF)
S2 Fig. Raw data from M. abscessus subsp. massiliense CFU in infected macrophages treated with Polydim-I peptide experiment.
https://doi.org/10.1371/journal.pone.0149729.s002
(PDF)
S3 Fig. Raw data from J774 macrophage cell line cytotoxic effects and hemolytic activity of Polydim-I peptide experiment.
https://doi.org/10.1371/journal.pone.0149729.s003
(PDF)
S4 Fig. Raw data from M. abscessus subsp. massiliense bacillary load reduction in IFN-γKO-infected mice after treatment with Polydim-I peptide experiment.
https://doi.org/10.1371/journal.pone.0149729.s004
(PDF)
S5 Fig.
Macrophage morphology after Polydim-I treatment and infection. Instant-Prov staining of: (A) Untreated macrophages; (B) Polydim-I peptide-treated macrophages; (C) macrophages infected with Mycobacterium abscessus subsp. massiliense isolate GO 06 (MOI 10:1); and (D) macrophages infected with M. abscessus subsp. massiliense isolate GO 06 and treated with Polydim-I peptide.
https://doi.org/10.1371/journal.pone.0149729.s005
(TIF)
S6 Fig. Histological analyses of the liver from mice treated with Polydim-I.
BALB/c mice were treated with 2 mg/kg/mLW (C and D) or 20 mg/kg/mLW (E and F) and 48 hours later the livers were processed and stained with HE. As controls, mice were treated with PBS (A and B). The results are presented at 40 x and 100 x magnification.
https://doi.org/10.1371/journal.pone.0149729.s006
(TIF)
Acknowledgments
The authors would like to thank the Labmic Core Facility from the Universidade Federal de Goias for use of the scanning electron microscope, Dr. Milton Adriano Pelli de Oliveira for supplying the IFN-γKO mice and all participants of the REDE CENTRO OESTE DE PESQUISA INOVATOXIN.
This work was financially supported through a grant from the CNPq-Rede Pró-Centro-Oeste de Pesquisa (n0: 564243/2010-8) and MCT/CNPq/FNDCT/FAPEG/MEC/CAPES/Pro-Centro-Oeste 031/2010 (n0: 201110267000106). The funding agency had no involvement in the study design, data collection, and data analysis or in the decision to submit this manuscript for publication.
Competing Interest: The authors declare no competing interests.
Author contributors: RCN, MMT, and KSS performed the antimycobacterial experiments and drafted the manuscript draft; JCS, LPS, ALB and MRM collected, purified and characterized the peptide; and MRM, AK and APJK designed the study and analyzed all data. All authors critically revised the manuscript and agreed to the final format.
Author Contributions
Conceived and designed the experiments: AK APJK. Performed the experiments: RCN MMT KSS JCS. Analyzed the data: JCS LPS ALB MRM. Contributed reagents/materials/analysis tools: APJK. Wrote the paper: RCN MMT LPS ALB MRM AK APJK.
References
- 1. Leao SC, Tortoli E, Viana-Niero C, Ueki SYM, Lima KVB, Lopes ML, et al. Characterization of mycobacteria from a major Brazilian outbreak suggests that revision of the taxonomic status of members of the Mycobacterium chelonae-M. abscessus group is needed. J Clin Microbiol 2009;47: 2691–2698. pmid:19571015
- 2. Cardoso AM, Sousa EM, Viana-Niero C, Bortoli FB, Neves ZCP, Leão SC, et al. Emergence of nosocomial Mycobacterium massiliense infection in Goiás, Brazil. Microbes Infect 2008; 10:1552–1557. pmid:18950729
- 3. Leao SC, Tortoli E, Euzéby JP, Garcia MJ. Proposal that Mycobacterium massiliense and Mycobacterium bolletii be united and reclassified as Mycobacterium abscessus subsp. bolletii comb. nov. designation of Mycobacterium abscessus subsp. abscessus subsp. nov. and emended description of Mycobacterium abscessus. Int J Syst Evol Microbiol. 2011;61:2311–2313. pmid:21037035
- 4.
Lee M, Sheng W, Hung C, Yu C, Lee L, Hsueh P. Mycobacterium abscessus complex infections in humans. 2015;21: 1638–1646.
- 5. Cardoso AM, Junqueira-Kipnis AP, Kipnis A. In vitro antimicrobial susceptibility of Mycobacterium massiliense recovered from wound samples of patients submitted to arthroscopic and laparoscopic surgeries. Minim Invasive Surg 2011;2011: 1–4.
- 6. Tettelin H, Davidson RM, Agrawal S, Aitken ML, Shallom S, Hasan NA, et al. High-level relatedness among Mycobacterium abscessus subsp. massiliense strains from widely separated outbreaks. Emerg Infect Dis. 2014;20: 364–371. pmid:24565502
- 7. Shang S, Gibbs S, Henao-Tamayo M, Shanley CA, McDonnell G, Duarte RS, et al. Increased virulence of an epidemic strain of Mycobacterium massiliense in mice. PLoS One. 2011;6: e24726. pmid:21931831
- 8. Duarte RS, Lourenço MCS, Fonseca LDS, Leão SC, Amorim EDLT, Rocha ILL, et al. Epidemic of postsurgical infections caused by Mycobacterium massiliense. J Clin Microbiol. 2009;47: 2149–2155. pmid:19403765
- 9.
ANVISA. Relatório descrito de investigação de casos de infecções por micobactérias não tuberculosas de crescimento rápido (mcr) no Brasil no período de 1998 a 2009. 2011;1: 51. Available: http://www.anvisa.gov.br/hotsite/hotsite_micobacteria/relatorio_descrito_mcr_16_02_11.pdf
- 10. Lyu J, Kim BJ, Kim BJ, Song JW, Choi CM, Oh YM, et al. A shorter treatment duration may be sufficient for patients with Mycobacterium massiliense lung disease than with Mycobacterium abscessus lung disease. Respir Med. 2014;108: 1706–1712. pmid:25245792
- 11. Patel AM, Shariff S, Bailey DG, Juurlink DN, Gandhi S, Mamdani M, et al. Statin toxicity from macrolide antibiotic coprescription. A population-based cohort study. Ann Intern Med 2013;158: 869–876. Available: http://dx.doi.org/10.7326/0003-4819-158-12-201306180-00004 pmid:23778904
- 12. Giuliani A, Pirri G, Nicoletto SF. Antimicrobial peptides: an overview of a promising class of therapeutics. Cent Eur J Biol 2007. pp. 1–33.
- 13. Haney EF, Hancock REW. Peptide design for antimicrobial and immunomodulatory applications. Biopolymers. 2013. pp. 572–583. pmid:23553602
- 14. Fox JL. Antimicrobial peptides stage a comeback. Nat Biotechnol. 2013;31: 379–382. pmid:23657384
- 15. Lohner K. New strategies for novel antibiotics: peptides targeting bacterial cell membranes. Gen Physiol Biophys 2009;28: 105–116.
- 16. Baptista-Saidemberg NB, Saidemberg DM, Ribeiro RA, Arcuri HA, Palma MS, Carneiro EM. Agelaia MP-I: a peptide isolated from the venom of the social wasp, Agelaia pallipes pallipes, enhances insulin secretion in mice pancreatic islets. Toxicon 2012;60: 596–602. pmid:22699107
- 17. Dias NB, de Souza BM, Gomes PC, Palma MS. Peptide diversity in the venom of the social wasp Polybia paulista (Hymenoptera): a comparison of the intra- and inter-colony compositions. Peptides 2014;51: 122–30. pmid:24239857
- 18. Gomes PC, de Souza BM, Dias NB, Brigatte P, Mourelle D, Arcuri HA, et al. Structure-function relationships of the peptide Paulistine: a novel toxin from the venom of the social wasp Polybia paulista. Biochim Biophys Acta 2014;1840: 170–83. pmid:24007897
- 19. Sousa EM, Bortoli FB, Amaral EP, Batista AC, Kipnis TL, Cardoso AM, et al. Acute immune response to Mycobacterium massiliense in C57BL/6 and BALB/c mice. Infect Immun. 2010;78: 1571–81. pmid:20123718
- 20. Griffith DE, Aksamit T, Brown-Elliott BA, Catanzaro A, Daley C, Gordin F, et al. An official ATS/IDSA statement: Diagnosis, treatment, and prevention of nontuberculous mycobacterial diseases. Am J Respir Crit Care Med. 2007;175: 367–416. pmid:17277290
- 21.
Lenaerts AJM, Gruppo V, Brooks JV, Orme IM. Rapid in vivo screening of experimental drugs for tuberculosis using gamma interferon gene-disrupted mice. 2003;47: 783–785. https://doi.org/10.1128/AAC.47.2.783
- 22. Teixeira LD, Silva ON, Migliolo L, Fensterseifer ICM, Franco OL. 2013. In vivo antimicrobial evaluation of an alanine-rich peptide derived from Pleuronectes americanus. Peptides 42:144–148. pmid:23416023
- 23. Tejada GM, Sánchez-Gómez S, Kowalski I, Kaconis Y, Andra J, Schurholz T, et al. Bacterial cell wall compounds as promising targets of antimicrobial agents I. Antimicrobial peptides and lipopolyamines. Curr drug. 2013;42: 144–148.
- 24. Lin CH, Tzen JTC, Shyu CL, Yang MJ, Tu WC. Structural and biological characterization of mastoparans in the venom of Vespa species in Taiwan. Peptides. 2011;32: 2027–2036. pmid:21884742
- 25. Lin CH, Hou RF, Shyu CL, Shia WY, Lin CF, Tu WC. In vitro activity of mastoparan-AF alone and in combination with clinically used antibiotics against multiple-antibiotic-resistant Escherichia coli isolates from animals. Peptides. 2012;36: 114–20. pmid:22561066
- 26. Wang K, Yan J, Dang W, Xie J, Yan B, Yan W, et al. 2014. Dual antifungal properties of cationic antimicrobial peptides polybia-MPI: membrane integrity disruption and inhibition of biofilm formation. Peptides 56:22–29. pmid:24642357
- 27. Wang Y, Ke XY, Khara JS, Bahety P, Liu S, Seow SV, et al. Synthetic modifications of the immunomodulating peptide thymopentin to confer anti-mycobacterial activity. Biomaterials 2014;35: 3102–3109. pmid:24411680
- 28. Boxtel RV, Lambrecht RS, Collins MT. Effects of colonial morphology and tween 80 on antimicrobial susceptibility of Mycobacterium paratuberculosis. Antimicrob Agents Chemother. 1990;34: 2300–2303. pmid:2088185
- 29. Rivas-Santiago B, Santiago CER, Castañeda-Delgado JE, León-Contreras JC, Hancock REW, Hernandez-Pando R. Activity of LL-37, CRAMP and antimicrobial peptide-derived compounds E2, E6 and CP26 against Mycobacterium tuberculosis. Int J Antimicrob Agents. 2013;41: 143–8. pmid:23141114
- 30. Padhi A, Sengupta M, Sengupta S, Roehm KH, Sonawane A. Antimicrobial peptides and proteins in mycobacterial therapy: Current status and future prospects. Tuberculosis (Edinb) 2014;94: 363–73.
- 31.
Yeaman MR, Yount NY. Mechanisms of Antimicrobial Peptide Action and Resistance 2003;55: 27–55. doi:0031-6997/03/5501-27
- 32. Hoshina MM, Santos LD, Palma MS, Marin-Morales MA. Cytotoxic, genotoxic/antigenotoxic and mutagenic/antimutagenic effects of the venom of the wasp Polybia paulista. Toxicon 2013;72: 64–70. pmid:23796727
- 33. Sonawane A, Santos JC, Mishra BB, Jena P, Progida C, Sorensen OE, et al. Cathelicidin is involved in the intracellular killing of mycobacteria in macrophages. Cell Microbiol. 2011;13: 1601–17. pmid:21790937
- 34. Dong N, Zhu X, Chou S, Shan A, Li W, Jiang J. Antimicrobial potency and selectivity of simplified symmetric-end peptides. Biomaterials. Elsevier Ltd; 2014;35: 8028–8039. pmid:24952979
- 35. Wang K, Zhang B, Zhang W, Yan J, Li J, Wang R. Antitumor effects, cell selectivity and structure-activity relationship of a novel antimicrobial peptide polybia-MPI. Peptides. 2008;29: 963–968. pmid:18328599
- 36. Pethe K, Bifani P, Jang J, Kang S, Park S, Ahn S, et al. Discovery of Q203, a potent clinical candidate for the treatment of tuberculosis. Nat Med. 2013;19: 1157–60. pmid:23913123
- 37. Adams KN, Takaki K, Connolly LE, Wiedenhoft H, Winglee K, Humbert O, et al. Drug tolerance in replicating mycobacteria mediated by a macrophage-induced efflux mechanism. Cell. 2011;145: 39–53. pmid:21376383
- 38. Rottman M, Catherinot E, Hochedez P, Emile JF, Casanova JL, Gaillard JL, et al. Importance of T cells, gamma interferon, and tumor necrosis factor in immune control of the rapid grower Mycobacterium abscessus in C57BL/6 mice. Infect Immun. 2007;75: 5898–5907. pmid:17875636
- 39. Choi GE, Shin SJ, Won CJ, Min KN, Oh T, Hahn MY, et al. Macrolide treatment for Mycobacterium abscessus and Mycobacterium massiliense infection and inducible resistance. Am J Respir Crit Care Med 2012;186: 917–25. pmid:22878281
- 40. Koh WJ, Jeon K, Shin SJ. 2013. Successful treatment of Mycobacterium massiliense lung disease with oral antibiotics only. Antimicrob Agents Chemother. 2013;57: 1098–100. pmid:23183432
- 41. De Groote MA, Gruppo V, Woolhiser LK, Orme IM, Gilliland JC, Lenaerts AJ. Importance of confirming data on the In Vivo efficacy of novel antibacterial drug regimens against various strains of Mycobacterium tuberculosis. Antimicrob Agents Chemother. 2012;56: 731–738. pmid:22143517
- 42. Rivas-Santiago B, Castañeda-Delgado J, Santiago CR, Waldbrook M, González-Curiel I, León-Contreras J, et al. Ability of innate defence regulator peptides IDR-1002, IDR-HH2 and IDR-1018 to protect against Mycobacterium tuberculosis infections in animal models. PLoS One. 2013;8: e59119. pmid:23555622
- 43. Sorimachi K, Akimoto K, Hattori Y, Ieiri T, Niwa A. Activation of macrophages by lactoferrin: secretion of TNF-alpha, IL-8 and NO. Biochem Mol Biol Int. 1997;43: 79–87. pmid:9315285
- 44. Hwang S, Wilk K, Budnicka M, Olsen M, Bangale Y, Hunter R, et al. Lactoferrin enhanced efficacy of the BCG vaccine to generate host protective responses against challenge with virulent Mycobacterium tuberculosis. Vaccine. 2007;25: 6730–6743. pmid:17698261
- 45. Feng Z, Huang J, Xu Y, Zhang M, Hu S. Dissociative disorder induced by clarithromycin combined with rabeprazole in a patient with gastritis. J Int Med Res. 2013;41: 239–43. pmid:23569151
- 46. Svanstrom H, Pasternak B, Hviid A. Use of clarithromycin and roxithromycin and risk of cardiac death: cohort study. Bmj. 2014;349: g4930–g4930. pmid:25139799
- 47. Ponce R, Abad L, Amaravadi L, Gelzleichter T, Gore E, Green J, Gupta S, et al. Immunogenicity of biologically-derived therapeutics: Assessment and interpretation of nonclinical safety studies. Regul Toxicol Pharmacol. Elsevier Inc.; 2009;54: 164–182. pmid:19345250
- 48. Heinig K, Wirz T, Schick E, Guenzi A. Bioanalysis of therapeutic peptides: Differentiating between total and anti-drug antibody bound drug using liquid chromatography-tandem mass spectrometry quantitation. J Chromatogr A. Elsevier B.V.; 2013;1316: 69–77. pmid:24119751
- 49. Lecaille F, Lalmanach G, Andrault P. Antimicrobial proteins and peptides in human lung diseases: A friend and foe partnership with host proteases. Biochimie. Elsevier Ltd; 2015;