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Journal of Clinical Microbiology, August 2005, p. 4041-4045, Vol. 43, No. 8
0095-1137/05/$08.00+0     doi:10.1128/JCM.43.8.4041-4045.2005
Copyright © 2005, American Society for Microbiology. All Rights Reserved.

Biochemical Differentiation and Comparison of Desulfovibrio Species and Other Phenotypically Similar Genera

Yumi A. Warren,¹ Diane M. Citron,^1* C. Vreni Merriam,¹ and Ellie J. C. Goldstein^1,2

R. M. Alden Research Laboratory, Santa Monica, California 90404,¹ UCLA School of Medicine, Los Angeles, California 90095²

Received 28 January 2005/ Returned for modification 5 April 2005/ Accepted 24 May 2005

Top Abstract Introduction Materials and Methods Results Discussion References

 
Seventeen human clinical isolates representing four species of Desulfovibrio were characterized using 16S rRNA gene sequences and tests for catalase, indole, nitrate, bile, urease, formate-fumarate stimulation, desulfoviridin, motility, and hydrogen sulfide production, plus susceptibility to antimicrobial agents. Eighty additional strains representing 10 phenotypically similar genera (Bilophila, Selenomonas, Capnocytophaga, Campylobacter, Bacteroides, Sutterella, Anaerobiospirillum, Dialister, Veillonella, and Mobiluncus) were included for comparison. All Desulfovibrio species produced H₂S and were desulfoviridin positive, and all Desulfovibrio species except D. piger were motile. The four Desulfovibrio species could be distinguished from each other using tests for catalase, indole, nitrate, urease, and growth on bile, with the following results (positive [+], negative [–], growth [G], and no growth [NG]): for D. piger, –, –, –, –, and G, respectively; for D. fairfieldensis, +, –, +, –, and G, respectively; for D. desulfuricans, –, –, +, +, and NG, respectively; and for D. vulgaris, –, +, –, –, and G, respectively. Resistance to the 10-µg colistin disk separated the Desulfovibrio species from most of the other genera, which were usually susceptible. These simple tests were useful for characterizing the Desulfovibrio species and differentiating them from other phenotypically similar genera.

Top Abstract Introduction Materials and Methods Results Discussion References

 
Sulfate-reducing bacteria are a diverse group of organisms that include Desulfovibrio, Desulfomicrobium, Desulfobulbus, Desulfobacter, Desulfococcus, Desulfosarcina, Desulfobacterium, Desulfonema, Desulfotomaculum, and Thermodesulfobacterium. This group of organisms has a variety of morphologies, biochemical properties, and nutritional requirements. With the exception of Desulfovibrio spp., they are found only in the natural environment (4, 30).

Desulfovibrio is one of the first genera described and the most thoroughly studied genus among the sulfate-reducing bacteria (4, 5). These are sulfate-reducing, nonfermenting, anaerobic, gram-negative bacilli characterized by the presence of a pigment, desulfoviridin, which fluoresces red in alkaline pH and blue-green in acid pH under long-wavelength UV light (15, 28) and by a strong sulfurous odor in broth media.

Desulfovibrio spp. are ubiquitous, found in the environment, such as soil, water, and sewage, as well as in the digestive tracts of animals and humans (4, 5, 17, 20, 25, 27, 31). Two of the Desulfovibrio species, D. piger and D. fairfieldensis, have never been isolated from outside the human body and can be considered natural inhabitants of the intestinal tract, where sulfates abound (10, 17, 19). The organisms are usually recovered from mixed cultures and may cause human infections. They have been isolated from a variety of sources, such as brain abscess (18, 21), periodontal pocket (2, 16), blood (11, 18, 22, 25), appendix (1), liver (26, 29), urine (14), and colon and bowel (6, 17, 18, 30, 31). Bacteremia appears to be the only instance where a Desulfovibrio sp. was the sole pathogen (11, 25).

The organisms grow very slowly, taking 3 to 5 days to produce tiny transparent, nonhemolytic colonies on anaerobic blood agar plates and therefore are easily missed or overgrown in mixed cultures (17, 18). Yet, identification of this group is important because similar organisms, such as Campylobacter or Bilophila wadsworthia, have quite different resistance patterns (3). Genetic methods, such as 16S rRNA gene sequencing (8, 9, 14, 29), have shown that among sulfate-reducing bacteria are organisms that are phenotypically similar yet phylogenetically diverse (4, 27). This is also true in reverse, as in the case of phenotypically dissimilar "Desulfomonas pigra," found by 16S rRNA gene sequencing to be closely related to Desulfovibrio spp. and hence reclassified into that genus (19).

Since genetic methods are not routinely employed in clinical laboratories, more-practical ways to identify fastidious organisms are still required. Commercial kits, such as the Rapid ANA II system (Remel, Kansas City, MO), Vitek ANI card (bioMerieux, St. Louis, MO), and API 20A (bioMerieux), are available, but Desulfovibrio species are generally nonreactive and/or are not included in the database (14, 22, 29). In one study, the BBL Crystal anaerobe identification system (Becton Dickinson, Sparks, MD) correctly identified all Desulfovibrio spp. and Bilophila sp. to the genus level. The genus identification was based on positive reactions for catalase and on hydrolysis of L-methionine and escosyl; however, the system failed to identify individual species (3).

Our laboratory has acquired 17 human strains of Desulfovibrio spp. over the past several years, 15 from intra-abdominal infections and two from blood cultures. Using those strains, we set about to devise a practical system for clinical laboratories to identify Desulfovibrio spp. to the species level and to differentiate them from other similar gram-negative bacilli. We also performed antimicrobial susceptibility testing on the Desulfovibrio isolates and compared the results to those of Bilophila wadsworthia.

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The organisms studied were Desulfovibrio spp. (17), Bilophila wadsworthia (11), Selenomonas spp. (6), Capnocytophaga spp. (6), Campylobacter spp. (6), Bacteroides ureolyticus (8), Sutterella wadsworthensis (8), Anaerobiospirillum spp. (7), Dialister pneumosintes (5), Veillonella spp. (8), Mobiluncus spp. (5), and 10 unnamed organisms. We also included ATCC strain 7757, originally classified as Desulfovibrio desulfuricans but subsequently reidentified as D. vulgaris (5).

All Desulfovibrio isolates and 26 of the other strains were extracted and amplified, using a universal primer and QIAGEN kits (QIAGEN, Inc., Valencia, CA), as previously described (9, 17, 18, 31). The DNA products were sent to a reference laboratory (Laguna Scientific Laboratory, Laguna Beach, CA) for sequencing. The sequences received were analyzed using BLASTN 2.2.9. and were compared with all the available bacterial sequences from the GenBank database. Through 16 S rRNA gene sequencing, our Desulfovibrio isolates were identified as 10 strains of D. fairfieldensis, three strains of D. desulfuricans, two strains of D. piger, and two strains of D. vulgaris.

All isolates were taken from 20% skim milk frozen at –70°C and transferred at least twice on brucella agar plates (Hardy Diagnostics, Santa Maria, CA) before testing. They were finally subcultured on brucella agar plates with kanamycin (1,000-µg), vancomycin (5-µg), and colistin (10-µg) differential antibiotic disks (Hardy Diagnostics, Santa Maria, CA). Further tests included catalase, spot indole, nitrate reduction, growth on bile, urease, growth stimulation with formate/fumarate, motility, desulfoviridin, and SIM (sulfide-indole-motility) medium tubes, as described in the Wadsworth-KTL Anaerobic Bacteriology Manual (13).

Nitrate disks (Hardy Diagnostics, Santa Maria, CA) were placed on the first quadrant of each inoculated plate and incubated in the anaerobic chamber for 72 h. After the addition of 1 drop each of nitrate reagents A and B (Anaerobe Systems, Morgan Hill, CA), the appearance of a red color indicated nitrate reduction to nitrite. If there was no color change to red, zinc powder was added. If still no color change occurred, other methods were used to confirm the test result. The alternative methods were prereduced anaerobically sterilized (PRAS) nitrate broth (Anaerobe Systems) and Rapid nitrate disks (Key Scientific Products, Round Rock, TX). The nitrate broth tubes were inoculated from a 0.5 McFarland turbidity standard inoculum suspension in brucella broth and incubated until they showed turbidity. Rapid nitrate disks were inoculated according to the package insert. The same nitrate reagents (reagents A and B) were used for all methods.

Bile growth tests employed two methods: differential bile disks (Hardy Diagnostics) and PRAS bile broth (Anaerobe Systems). Bile disks were placed on the second quadrant where more-distinct colonies could be seen. Bile broth was inoculated from the same inoculum suspension as the nitrate broth.

Urea disks (Hardy Diagnostics) were placed in tubes, which were inoculated with a heavy suspension of the isolate, and incubated up to several days to detect weak reactions. After 24 h, a positive reaction gave a pale pink color, and a negative test appeared orange. No additional positive reactions were detected after 24 h.

Motility tests were also performed using two methods, one method using wet mount and the other using motility tube media with an indicator (Hardy Diagnostics). The presence of desulfoviridin pigment was tested by swiping the colonies with a cotton-tipped swab and then adding 1 drop of 2 N NaOH directly onto the swab. The reaction was immediately observed in a dark box under UV light at 365 nm. Red fluorescence indicated a positive reaction.

Susceptibility testing was performed by agar dilution according to the procedure described in CLSI (formerly NCCLS) M11-A6 (24).

Top Abstract Introduction Materials and Methods Results Discussion References

 
Biochemical test results for the different species are shown in Table 1. The desulfoviridin pigment was observed by red fluorescence and detected in both Desulfovibrio spp. and Bilophila wadsworthia, and the SIM medium tubes for both genera turned black within several days, indicating H₂S production. It was observed that D. desulfuricans and D. vulgaris turned the SIM tubes completely black in 1 day. On the other hand, D. piger and D. fairfieldensis started turning black in 3 days; in general, D. fairfieldensis required the longest time to turn black.

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TABLE 1. Biochemical reactions for Desulfovibrio and similar organisms

Desulfovibrio spp. and Bilophila sp. could be differentiated by the 10-µg colistin differential disk pattern, which showed resistance for the former and susceptibility for the latter. Of the Desulfovibrio spp., D. piger was distinguished by the lack of motility, whereas the other three species were motile. All 10 D. fairfieldensis strains produced catalase, unlike the other Desulfovibrio spp., which were all catalase negative. Distinguishing features of all three D. desulfuricans strains were an inability to grow on bile and positive urease results after 24 h. Both D. vulgaris clinical isolates, as well as the ATCC 7757 strain, were the only species that were indole positive.

The nitrate test result was recorded as positive if any one of the three methods tested positive. All 10 D. fairfieldensis strains and all three D. desulfuricans strains were nitrate positive. Eleven of these 13 strains were positive with the initial nitrate disk tests, and two were positive only with the rapid test. Using nitrate disks, it was our observation that the growth had to be very heavy to have positive results for nitrite and that the addition of zinc powder to a negative test did not give a strong red color. The rapid nitrate test was the most sensitive of the three methods and gave only one false-negative result.

The ability to grow on bile was easiest to see on blood agar with bile disks. Most of the strains that grew on bile grew poorly in PRAS peptone-yeast broth with 20% bile.

The semisolid motility agar failed to show motility of the Desulfovibrio strains, and their motility was best demonstrated by microscopic examination of a wet mount. Three of four Selenomonas flueggei strains and one of four Anaerobiospirillum thomasii strains did not show any sign of motility at room temperature or at 37°C. Since these are motile organisms, they apparently lost their flagella during frozen storage. Although Capnocytophaga spp. are gram-negative bacilli, half the strains tested were susceptible to the vancomycin differential disk, which might indicate borderline susceptibility and suggests a gram-positive-like cell wall.

ATCC strain 7757 showed biochemical test results consistent with those of D. vulgaris as expected, positive for indole and bile growth tests and negative for all the other tests.

Four groups of organisms were categorized as unnamed organism groups I, II, III, and IV. The five organisms in unnamed organism group I were originally thought to be D. piger, with which they were morphologically consistent. They showed similar gram stain morphologies and were susceptible to kanamycin and resistant to vancomycin and colistin differential disks, typical for the genus. However, they were negative for the desulfoviridin pigment and H₂S production in SIM medium tubes. The PCR sequences of all five strains were similar to each other but did not match any sequences in the GenBank database. The other five strains were also phenotypically similar to one of the comparator genera but did not match exactly and thus were sequenced to determine their identity.

The list of antimicrobials and their MICs are summarized in Table 2. All strains of Desulfovibrio spp. and Bilophila sp. were susceptible to chloramphenicol and metronidazole, most were susceptible to imipenem and clindamycin, and in general, they were resistant to penicillin. D. fairfieldensis was significantly more resistant than the other three Desulfovibrio spp. and also Bilophila sp.: all 10 D. fairfieldensis strains were resistant to piperacillin-tazobactam and ceftriaxone, and most were resistant to ticarcillin-clavulanic acid, cefoxitin, and ertapenem. D. vulgaris appeared to be the most susceptible species in this genus, with our two strains susceptible to all the antimicrobials tested, including penicillin. The nitrocefin disk test for beta-lactamase gave variable results, with only three strains among Desulfovibrio spp. being positive.

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TABLE 2. In vitro susceptibilities of Desulfovibrio species and Bilophila wadsworthia to 14 antimicrobial agents

Top Abstract Introduction Materials and Methods Results Discussion References

 
Phylogenetically related by DNA profile, Desulfovibrio spp. and Bilophila sp. are found in similar sites of the human body (23) and also share phenotypic characteristics. In fact, before Bilophila sp. was first described, positive tests for the desulfoviridin pigment and H₂S production would have classified the organism as Desulfovibrio spp. However, the two genera have different mechanisms for sulfate reduction (15, 23, 26).

Loubinoux et al. (18) reported somewhat different biochemical reactions from ours for some of their isolates. Firstly, two out of four strains identified as D. desulfuricans in their study were catalase and nitrate positive, whereas all three of our strains of D. desulfuricans were catalase negative. Secondly, the four strains of D. fairfieldensis in their study were described as catalase positive and nitrate negative, whereas all 10 of our strains of D. fairfieldensis were consistently both catalase and nitrate positive. The reason for this discrepancy is not clear but may be due to differences in test methods.

Loubinoux et al. (17) suggested that D. fairfieldensis, D. desulfuricans, and D. piger were the three species that have been isolated from human sources. Our study and Johnson et al. (12) have reported D. vulgaris from human sources as well.

The first known case of Desulfovibrio desulfuricans infection was reported by Porschen et al. in 1977 (25), and the strain was described as catalase positive but urease and nitrate negative (the nitrate reaction was too weak to be considered positive). According to our own test results, however, D. desulfuricans, as identified by sequence matching to a level greater than 99%, is characterized by positive urease and nitrate tests. D. fairfieldensis was the only species that was both catalase and nitrate positive, and therefore it is more likely that the 1977 case is actually the first reported instance of infection by D. fairfieldensis. This biochemical characterization would agree with the finding by Dzierzewics et al., who analyzed D. desulfuricans through fatty acid profiles (7) and genetic fingerprinting (8) and found great homogeneity among the intestinal strains of this organism, making the identification of Porschen's isolate unlikely.

Except for isolates from case reports (11, 14, 18, 22, 29), to date, there are few studies that report antimicrobial susceptibilities for Desulfovibrio organisms. Lozniewski et al. (20) tested 16 isolates and found that all were susceptible to imipenem and metronidazole and resistant to penicillin, piperacillin-tazobactam, and cefoxitin. Although which species were tested was not indicated in their report, the susceptibility results match those we obtained with D. fairfieldensis.

Finally, our own results agree with those of Devereux et al., who suggested that 16S RNA showed D. desulfuricans ATCC 7757 to be closely related to D. vulgaris (5). This is also borne out by the MICs for that strain, which, like other D. vulgaris strains, are the least resistant of the Desulfovibrio organisms.

Loubinoux et al. (18) suggested that Desulfovibrio fairfieldensis may be the most potentially pathogenic among all Desulfovibrio species, and our study found that this species was the most common isolate from intra-abdominal specimens, as well as being the most antimicrobial resistant. Because of variation in susceptibility patterns, it is therefore clinically important to identify Desulfovibrio spp. to the species level.

Conclusion. More sulfate-reducing organisms will likely be isolated from human sources in the future, and their identification properties may become more complex. Currently, identification of human isolates of Desulfovibrio spp. to the species level can be accomplished by performing gram stain (typically the organisms stain bipolar), differential disks, catalase, indole, nitrate, urease, motility, H₂S production in SIM medium, and detection of a desulfoviridin pigment. The last test mentioned is the key reaction to distinguish Desulfovibrio spp. and five organisms in unnamed organism group I that were phenotypically very similar to Desulfovibrio. Additional studies are currently under way to further characterize and name the unidentifiable strains.

 
* Corresponding author. Mailing address: R. M. Alden Research Lab, 2001 Santa Monica Blvd., Suite 685W, Santa Monica, CA 90404. Phone: (310) 453-7820. Fax: (310) 453-7670. E-mail: d.m.citron{at}verizon.net.

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Journal of Clinical Microbiology, August 2005, p. 4041-4045, Vol. 43, No. 8
0095-1137/05/$08.00+0     doi:10.1128/JCM.43.8.4041-4045.2005
Copyright © 2005, American Society for Microbiology. All Rights Reserved.

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