TRACING THE CRIMINAL Part Five: Gram-Negative Criminals II Institute for microbiology presents: L Medically important G– rods Story Endo Group P04 grows Enterobacteriaceae (GLC +, OXI –) P04 grows Vibrionaceae (GLC +, OXI +) P04 does not Campylobacter and Helicobacter 3. + 4. grows G- non-fermenters (GLC –) 1. + 2. does not Pasteurellaceae P06 does not Legionella, Bordetella, Brucella etc. 14 HEIN haemophilus http://medinfo.ufl.edu [USEMAP] Summary Clinical characteristics – Pasteurellaceae Clinical characteristics – G– glucose non-fermenters Diagnostics of Pasteurellaceae Diagnostics of G– glucose non-fermenters Clinical characteristics – Pasteurellaceae Story One •Four-years old Jimmy is a fine boy, but his parents are members of a strange religious society and so they do not wish get him vaccinated. They would like to keep him at home, but as they have to be at work, they sent him to a nursery. •After a month Jimmy started to have a cold, difficult breathing, gasping for air, and it was so serious that emergency had to be called. Emergency even thought about coniotomy, but finally it was not necessary. It was epiglottitis – a disease not very common nowadays… Who did this to Jimmy? •Criminal: Haemophilus influenzae ser. b (Hib) •Haemophili are short Gram negative rods. •Haemophili belong to the family Pasteurellaceae, together with Pasteurella (see later) 28 Hib http://www.co.monroe.mi.us Classification of haemophili •Haemophilus influenzae –capsular type b (Hib) – preventable (vaccine) –capsular types a, c, d, e, f –non-encapsulated strains •Haemophilus parainfluenzae (much more common, much less pathogenic) •Haemophilus aphrophilus and many other species •Haemophilus ducreyi, causative agent of a sexually transmitted disease ulcus molle Pathogenicity of haemophili •The most severe diseases caused by haemophili are epiglottitis, meningitis and sepsis. This is mostly typical for Haemophilus influenzae, serotype b. •Other common diseases are otitis media and sinuisitis (after Streptococcus pneumoniae and together with Moraxella catarrhalis) •Their presence in throat is very common and their pathogenic role is very questionable. Especially in a case of Haemophilus parainfluenzae, we usually do not suppose them to be pathogen. [USEMAP] A Haemophilus disease 10 Haemophilus-Type-b http://www.immune.org.nz Ulcus molle •It is a sexually transmitted disease found mostly in sub-tropical and tropical countries •Ulcus molle – chancroid – caused by Haemophilus ducreyi •Ulcus durum – chancre – one of symptoms of syphilis, caused by Treponema pallidum • 22 Cancro www.fmt.am.gov.br Story Two •Joana was walking in gardens as usual. Unfortunately, one garden fence was too old and rotten and the dog behind too strong. The dog run out and Joana was bitten into her leg. •The owners of the dog had proven that the dog has been vaccinated against rabies. Nevertheless, some pus soon occurred in the wound. The pus was sent to the laboratory. And the criminal was… Pasteurella multocida •Pasteurella multocida is normal respiratory microbiota in dogs. •In humans, it causes mainly pyogene wound inflammations after being bitten by a dog or another animal. •It smells similarly as haemophilus (some people say „like old rag“), but it grows on blood agar (not Endo agar). •The morphology of colonies: something between Streptococcus and Enterococcus, but it is vancomycin resistant and this is suspicious to the microbiologist (especially with parallel susceptibility to penicillin) Pasteurella multocida 19 pasteurella 18 encefalite_bovina_f4 [USEMAP] http://www.biologico.sp.gov.br http://library.thinkquest.org Clinical characteristics – Gram– glucose non-fermenting bacteria Story Three •Mr. P. is a pyromaniac. Several days ago, he burned himself and his burn was inflammated. He was hospitalised on a specialized centre and felt very badly. Doctors knew that it had no sense to try antibiotics accidentally, so they performed a swab from burn. Thanks to this, a targeted therapy was found, and Mr. P. was healed. Of course, sooner or later, he will probably play with his matches again (like some students of these practical exercises). Who is guilty this time? •Pseudomonas aeruginosa, the most common of „Gram– non-fermentation bacteria“ (G– NF) •On the other hand, the guilty one could be any of that group, e. g. Acinetobacter, Burkholderia cepacia or Stenotrophomonas maltophilia •Those bacteria are mostly strict aerobes, instead of fermentation of sugars, they utilize them by aerobic respiration, and their adaptation to outer environment is obvious also in other properties – they have low temperature optimum and they are often pigmented, so they fight with sunlight in outer environment 5 Photo: Inst. for Microbiology (web of the Institute), photo by prof. Skalka Green pigmented strain of Pseudomonas aeruginosa on MH 04 280px-Pseudomonas 07 P 08 pseudo 05 P Pseudomonas strain with blue pigmentation http://de.wikipedia.org textbookofbacteriology.net textbookofbacteriology.net www.uiowa.edu Pathogenicity of G– NF •Commonly: bacteria from outer environment, often plant pathogens, „not-brave-bacteria“, which are not able to infect a healthy person. Their aims are patients with burns, clients of emergency units, transplant centres, e. t. c. •They often cause wound infections, can be found in respiratory ways, and even in the bloodstream of hospitalized persons. •So they are important causative agents of nosocomial infections •Sometimes it is difficult to differentiate between an infection and a colonisation – especially in superficial wounds it is often useless to use other than topical antibiotics In disabled persons, they can cause even such problems as a nail inflammation 03 pseudomonas%20i%20nogl Island www.kvarts.is Story Four •Linda was a poor girl: she suffered from an inborn disease, cystic fibrosis. •Her lung surfactant was different from surfactant of healthy people. So, it was infected very often. •It was Staphylococcus aureus last time . This time it was different: the causative agent was Burkholderia cepacia, one of G– non-fermentating bacteria. Non-fermenters and Cystic fibrosis •Cystic fibrosis is a severe, inborn lung disease, with failure of production of normal lung surfactant. This leads to changed characteristics of lungs, including many times increased risk of infection •Most common causative agents are Pseudomonas aeruginosa, Burkolderia cepacia and Staphylococcus aureus. Strains often become polyresistant and many children with cystic fibrosis die very young. 42 cystic fibrosis 43 hdc_0001_0001_0_img0072 http://www.humanillnesses.com 44 4083-250px-cftreatmentvest2-cystic-fibrosis http://goldbamboo.com More Gram non-fermenters: Pseudomonas fluorescens •P. fluorescens is very similar to P. aeruginosa, but under UV-lamp, fluorescence occurs • 31 PSFL http://www.bact.wisc.edu Burkholderia cepacia •Burkholderia cepacia is responsible for rotten onions (Allium cepa), so it is a typical plant pathogen • 32 onion_compend http://www.apsnet.org 34 Burkholderia%20cepacia%20fig18 http://www.microbelibrary.org Burkholderia pseudomallei •Burkholderia pseudomallei is causative agent of mellioidosis. Related B. mallei is causative agent of malleus (a zoonosis) • 33 bpseud http://www.asm.org Stenotrophomonas maltophilia •Stenotrophomonas maltophilia is a long name, but it is possible to learn it easily: it is narrow-nutrition-unit maltose-loving, so it is a „bacterial panda“, chewing maltose instead of bamboo J. • 35 STMA 36 StenoMalto-BAP-24-h 37 Stenotrophomonas%20maltophilia%20fig20 http://www.scielo.cl http://clinicalmicrobiology.stanford.edu http://www.microbelibrary.org 40 acinetc1259th Acinetobacter sp. •Greek: a-kineto- = „non motile“ • 38 Acinetobacter_calcoaceticus_04-2Tag-Columbia 39 ACBA http://www.bakteriologieatlas.de http://www.microbelibrary.org http://www.buddycom.com Bacterial metabolism and relation of bacteria to oxygen •We know already that G– non-fermenters are bacteria that do not ferment sugars, but they perform aerobic respiration. Let‘s compare two bacteria: •Escherichia coli lives in the intestine. It has enough nutrients, but not enough oxygen (unlike other gases J), so it prefers glucose (and other substrates) fermentation. Escherichia coli is a facultative anaerobe. Some other intestinal bacteria are strict anaerobes. •On the other hand, Pseudomonas has oxygen enough, but nutrients not enough. It uses aerobic respiration: enables better exploitation of nutrients. Pseudomonas is a strict aerobe. Pseudomonas as a strict aerobe (unlike other bacteria) •Unlike strain I (Escherichia coli) and strain II (Bacterioides fragilis, a strict anaerobe), Pseudomonas aeruginosa (strain III) is a strictly aerobic bacterium (more about Bacteroides fragilis in P07) Strain Broth VL-broth Result III growth clear Strictly aerobic bacterium II clear growth Strict anaerobe I growth growth Facultative anaerobe [USEMAP] Diagnostics of Pasteurellaceae Methods in Pasteurellaceae diagnostics •Direct methods –Microscopy – short G– rods –Culture – Pasteurellaceae do not grow on Endo agar, Haemophilus even does not grow on Blood agar (except being co-cultivated with another microbe) –Biochemical identification – it is possible to use it –Antigen analysis – used in haemophili (Hib) –Nucleic acid detection – not used routinely •Indirect methods used rarely Differentiation of Pasteurellaceae (differential diagnostics) •Gram staining: Gram– rods × other bacteria •Endo medium: as we now, among clinically important bacteria, only Enterobacteriaceae, Vibrionaceae and Gram– non-fermenters are able to grow. Pasteurellaceae do not grow. •Pasteurellaceae are detected by typical smell, biochemical properties, growth on individual media, typical antibiotic susceptibility etc. 11 HaemophilusInfluenzae Haemophilus and Pasteurella diagnostic •Pasteurella is able to grow on blood agar •Haemophili are not able to grow on blood agar, they are not able to „open the RBC“. So, they grow only on chocolate agar or Levinthal agar (filtrated chocolate agar) •On BA, they are able to grow in presence of a bacterium that „opens the RBC“ (satellite phenomenon). Such bacterium is e. g. Staphylococcus aureus. •They grow in tiny colonies, so we use a disc to inhibit the growth of other bacteria (bacitracin, but in higher concentration than in bacitracin test) http://www.uni-ulm.de Satellite phenomenon •As we already know, haemophili need factors from RBC, but they are not able to break an RBC. They need the RBCs to be broken –by heating – chocolate agar –by presence of another microbe •Satellite phenomenon is an example of the second way how to make haemophili be able to exploit blood factors. That means the growth of Haemophilus around Staphylococcus line only. •Presence of satellite phenomenon is a confirmation, that our bacterium is really a Haemophilus Haemophili on chocolate agar (left) and as a satellite on blood agar Haemophilus sp. - kultivace na čokoládovém agaru . Klikni! ChA Haemophilus sp. - satelitový fenomén. Klikni! BA (satelite) Photo: Inst. for Microbiology (web of the Institute) Satellite once more 26 satelit http://phil.cdc.gov Detection of haemophili •Haemophili are more resistant than the bacteria of the common flora, so they grow inside the zone, but only near to staphylococcus line (satellite phenomenon) Klin9 Klin9a Photo: Inst. for Microbiology Growth factors of Haemophili (= determination of individual species) •haemophili need factors from blood, but the need of individual factors is species specific. –H. parainfluenzae needs factor V (= NAD) –H. aphrophilus needs factor X (= hemin) –H. influenzae needs both factors. •We use discs with these factors: one with X, another with V, and the third with a mixture of both of them. Growth factor test of Hemophili •One disk is with factor X, second with factor V, third a mixture HEAP HEIN HEPA H.influenzae - růst kolem disku s faktory X+V. Klikni! H.parainfluenzae - růst kolem disku s faktorem V a s faktory X+V. Klikni! H. influenzae (left), H. parainfluenzae (right) Photo: Inst. for Microbiology Haemophilus influenzae: antigen analysis (intra-species diagnostics •Antigen analysis in Haemophilus influenzae is performed like in other bacteria. The main goal is differentiation of Hib. Today, we have commercially available sets, containing e. g. latex particles. We try to assess the capsular type of H. influenzae (a, b, c, d, e, or f). When the strain does not agglutinate with any sera, it is probably an non-encapsulated strain •Formerly, so named co-agglutination with Staphylococcus strain was used: agglutinate was more dense because of Staphylococcus binding the Fc-end of anti-haemophilus antibody Antigen analysis of H. influenzae: an example of the result •The agglutination results for haemophili are observed similarly as other agglutination reactions 49 stafaurex předělaný na hemofily collage with use of: www.microbes-edu.org Detection of Pasteurella using typical susceptibility pattern •No Gram-negative bacterium is susceptible to vancomycin. Vancomycin can be used for Gram-positive bacteria only, it is very strong; all streptococci and majority of staphylococci and enterococci are susceptible •On the other hand, very little bacteria are susceptible to penicillin, especially among G– bacilli. •So, susceptibility to penicillin and resistance to vancomycin is quite typical for Pasteurella. Tests of atb susceptibility •haemophili do not grow on MH agar •Usually Levinthal agar (filtrated chocolate agar) is used for diffusion disc test – for this purpose, this agar is better than classical chocolate agar •Our laboratory uses „Haemophilus agar“, similar to Levinthal agar •Reading of the zones is the same as for any other bacteria Antibiotic susceptibility testing: An example of Pasteurellaceae antibiotic set [USEMAP] Antibiotic Abbr. Reference zone Ampicilin (AMP) AMP C ≥ 16 / R < 16 Ko-amoxicillin (AMC) AMC C ≥ 16 / R < 16 Cefuroxime (CXM) CXM C ≥ 25 / R < 25 Chloramfenicole (C) C C ≥ 28 / R < 28 Tetracyclin (TE)* TE C ≥ 25 / R < 22 Co-trimoxazol (SXT) SXT C ≥ 23 / R < 20 *valid also for doxycyclin Diagnostics of Gram–non-fermenters Methods for G– non-fermenters •Direct methods –Microscopy – mostly G– rods, but Acinetobacter is a G– coccus –Culture – non-fermenters grow on majority of media, including Endo agar. As glucose-non fermenters, they are mostly also lactose-non fermenters, but their colonies are sometimes quite dark, because of pigmentation –Biochemical identification – possible, but tests checking aerobic respiration (not fermentation) should be used. We also use mostly decreased temperature and prolonged incubation –antigen analysis, nucleic acid detection – not used routinely •Indirect methods used rarely Differentiation of G– non-fermenters (differential diagnostics) •Gram staining: Gram– rods × other bacteria •Endo agar: they grow. As glucose-non fermenters, they are mostly also lactose-non fermenters, but their colonies are sometimes quite dark, because of pigmenation •Non-fermenters are differentiated from enterobacteria/vibria by no fermentation of glucose (e. g. Hajna medium remains completely red after culture, no colour change; but eventual light brown colour does not matter, it is due to presence of pigments) Further diagnostics of individual genera and species of G– NFs •Pseudomonas is usually detected by: –Presence of typical odour (young cultures) –Pigments, mostly green, sometimes blue or maroon. Best visible on MH, worse on BA and Endo agar –Positive oxidase •Other non-fermenters, or not-sure Pseudomonas, should be differenciated biochemically, e. g. by NEFERMtest 24 Pseudomonas on MH agar and other media •Remember, that MH agar itself is nearly colourless (or slightly yellowish). •All green colour you see is product of Pseudomonas, or more precisely, of its pigment pyoverdin •On BA and Endo, pigment production is not so strong, but partially visible, too. Nevertheless, something more visible on these media is the typical pearl smooth surface of the colonies Oxidase test in non-fermenters •Among the most common G– non-fermenters, Pseudomonas is oxidase positive, Burkholderia usually too; on the contrary, Stenotrophomonas and Acinetobacter are usually negative . 08 oxidase3 medic.med.uth.tmc.edu/path/oxidase.htm NEFERMtest 24 •For precise biochemical identification of G– non-fermenters we use mostly NEFERMtest 24 (or a similar test). •It is a triple-strip (not double as last week) •There is a different way of code-formation than for (for example) ENTEROtest 16: –first number is 0 (oxidase –) or 1 (oxidase +) –next 6 numbers come from columns H to C –columns B and A are not counted (they are eventually used for more detailed determination) P1010002upr Photo: Inst. for Microbiology (web of the Institute), photo O. Z. NEFERMtest 24 •One frame is used for four triple-strips (for four strains). Each strain is detected using 24 reactions. •Requires 30 °C, 48 h Antibiotics susceptibility of G– NF •G– non-fermenters may be tested on common media. •We use strong antibiotics, that should not be used for other infections •We use: –3rd generation cephalosporins* (but only some of them – „anti-pseudomonad“ ones, like ceftazidime) –Anti-pseudomonad penicillins, monobactams and carbapenems* (imipenem, piperacillin/tazobactam) –aminoglycosides (gentamicin, amikacin) –fluoroquinolones (ciprofloxacin, ofloxacin) –polypeptides (colistine) –*or combinations with beta-lactamase inhibitors An example of Pseudomonas atb set Antibiotic Abbrev. Reference zone Piperacilin+tazobactam (TZP)* TZP C ≥ 18 / R < 18 gentamicin (CN) CN C ≥ 15 / R < 15 ofloxacin (OFL) OFL C ≥ 16 / R < 13 ciprofloxacin (CIP) CIP C ≥ 25 / R < 22 ceftazidime (CAZ) CAZ C ≥ 16 / R < 16 colistin (CT) CT C ≥ 11 / R < 11 *antipseudomon. peniciline + b-lactamase inhibitor P.aeruginosa - diskový test citlivosti na antibiotika. Klikni! Photo: Inst. for Microbiology Pseudomonas aeruginosa susceptibility •On this picture, Pseudomonas aeruginosa is probably susceptible to all tested antibiotics, but it is possible set containing only discs with special anti-pseudomonad drugs. There exist poly-resistant strains that have secondary resistances even to such antibiotics. •Producers of so called metalo-betalactamases (MBL) use to be only susceptible to amikacin and colistin. E-test - kapkový tvar inhibiční zóny. Klikni! It is also possible to use E-test (here) or microdilution test Photo: Inst. for Microbiology The End 30 PSFL [USEMAP] http://www.scienceclarified.com [USEMAP] Inflammation of external ear – otitis media (bonus) •Common in children (short horizontal Eustach tube) •Caused by: Streptococcus pneumoniae, Haemophilus influenzae, Moraxella catarrhalis •In chronical cases also some G– rods •It is necessary to differentiate otitis externa: here Staphylococcus aureus is the main pathogen (as in other skin inflammations), local therapy, e. g. Framycoin drops Otitis media 10 JAMA_Childrens_EarInfections_lev20_AcuteOtitsMedia_JPP_01 09 otitis media [USEMAP] http://www.medem.com/MedLB/article_detaillb.cfm?article_ID=ZZZPMV6D1AC&sub_cat=544 http://www.otol.uic.edu/research/microto/Microtoscopy/acute1.htm Examination and treatment of otitis media •Therapy is indicated in case of a real inflammation (pain, redness, fever) and it does not react to anti-inflammatory treatment •Drug of choice is amoxicilin (e. g. AMOCLEN), an alternative is co-trimoxazol •Ear swab examination is meaningful only after paracentesis •Otherwise it is also possible to examinate pyogenic liquid taken during paracenthesis [USEMAP]