Tuberculosis Genotyping Project, United States

Molecular Differentiation of Mycobacterium tuberculosis Strains without IS6110 Insertions

Kerry H. Lok,* William H. Benjamin, Jr.,*  Michael E. Kimerling,* Virginia Pruitt,† Monica Lathan,‡ Jafar Razeq,‡ Nancy Hooper,‡ Wendy Cronin,‡ and Nancy E. Dunlap*
*University of Alabama at Birmingham, Birmingham, Alabama, USA; †Alabama Department of Public Health, Montgomery, Alabama, USA; and ‡Maryland Department of Health and Mental Hygiene, Baltimore, Maryland, USA

Suggested citation for this article: Lok KH, Benjamin WH Jr, Kimerling ME, Pruitt V, Lathan M, Razeq J, et al. Molecular differentiation of Mycobacterium tuberculosis strains without IS6110 insertions. Emerg Infect Dis [serial online] 2002 Nov [date cited];8. Available from: URL: http://www.cdc.gov/ncidod/EID/vol8no11/02-0291.htm

By using standard restriction fragment length polymorphism, 6 zero-copy IS6110 Mycobacterium tuberculosis isolates were identified from 1,180 Maryland isolates as part of the National Tuberculosis Genotyping and Surveillance Network Project. By using various genotyping methods, we demonstrated that this zero band cluster can be differentiated into six genotypes.

IS6110 restriction fragment length polymorphism (RFLP) has been used to investigate Mycobacterium tuberculosis transmission within populations since the early 1990s (1–4). However, some strains do not have any IS6110 insertions and thus are zero-band strains (5) and are considered a single IS6110 cluster by exclusion (5,6). These zero-band strains are rare in the United States and usually are found in persons from Southeast Asia. Recently, the spacer oligonucleotide typing (spoligotyping) technique was used to divide some zero-copy IS6110 strains into subclusters that are associated with distinct geographic origins. As part of the National Tuberculosis Genotyping and Surveillance Network, six zero-copy IS6110 strains were identified in persons from Maryland during a 5-year period. We conducted further molecular characterization of these strains to ascertain if they were closely related.

Six zero-copy IS6110 isolates were identified from 1996 to 2000. These isolates, negative for IS6110 by RFLP analysis, were from 1,180 Maryland cases. The isolates were collected as part of  the genotyping network. Of the six patients, three were from Vietnam (two shared a common surname), and the others came from India, Iraq, and Liberia. None were linked epidemiologically to one another. 

We identified all isolates as M. tuberculosis complex with BACTEC NAP test (BACTEC 460, BD Diagnostic Systems, Sparks, MD) and AccuProbe (Gen-Probe, San Diego, CA) before they were sent to the Alabama Regional Genotyping Laboratory. The isolates were fingerprinted at least twice by IS6110 RFLP to rule out technical error in the RFLP procedure. After error was ruled out, all zero-copy strains were then tested with three secondary typing methods. 

M. tuberculosis isolates were cultured on Lowenstein-Jensen or 7H11 Middlebrook plates for at least 4 weeks before DNA extraction. Chromosomal DNA was extracted from the isolates with chloroform-isoamyl alcohol, and RFLP was performed according to international standards (7). For the zero-copy IS6110 strains, membranes with negative lanes were subjected to at least twice the normal exposure time to rule out the possibility of missing a faint band.

The use of spoligotyping was based on the presence or absence of 43 variable spacers in the direct repeat (DR) region of M. tuberculosis. Spoligotyping membranes were purchased from Isogen Bioscience BV (Isogen, Bilthoven, the Netherlands). We followed the manufacturer’s recommendations for hybridizing polymerase chain reaction (PCR) products, as described by Groenen and colleagues (8). The numbering of the spacer regions was done as reported previously (8). Excel (Microsoft Corp., Redmond, WA) was used to analyze the spoligotyping results. For national database reporting, we converted the spoligotyping image into an octal-digital format based on the protocol set by colleagues and the genotyping network (9).

After AluI digestion, the DNA was transferred to a nylon membrane for polymorphic guanine cytosine-rich repetitive sequence (PGRS) Southern blotting. Southern-blotting protocol was followed at the genotyping network except for the use of the plasmid pTBN12 as the probe. The results were compared visually (10).

The variable number of tandem repeats (VNTR) typing method was employed, as previously described, to further investigate these strains (11). The sizes of the fragments were determined by using a DNA ladder and amplicons from strain H37Rv (11).

Four different spoligotype patterns were obtained for the six isolates (Table). Three isolates had the same spoligotype patterns (designated Centers for Disease Control and Prevention [CDC] spoligotype 258): isolates 1–3 with an absence of spacers 19–41. The other three patterns were distinct with deletion of spacers as follows: isolate 4 (deletions at 4–11, 13–36, and 40); isolate 5 (deletions at 12–43); and isolate 6 (deletions at 33–34).

PGRS also yielded four patterns and divided the strains into groups that were identical to those found with spoligotyping (Figure 1). Three isolates (lanes 1–3) had the same banding pattern, and one isolate (lane 6) had a similar pattern that differed only by the presence of a double rather than single band at 2,760 bp. The two remaining isolates had distinct patterns (lanes 4 and 5). The lack of variability in the PGRS patterns suggests that these strains may be related. The genomes of these strains may be more stable than strains with IS6110.

	Figure 1
	Click to view enlarged image Figure 1. Polymorphic guanine cytosine-rich repetitive sequence restriction fragment length...
	Figure 2
	Click to view enlarged image Figure 2. The variable number of tandem repeats results of three zero-copy...

We used VNTR to genotype the three samples (lanes 1–3) (Figure 1) that had identical spoligotype and PGRS results. The profile of these three isolates, which were obtained from three Vietnamese patients, were differentiated only by loci exact tandem repeats (ETR)-A and ETR-D (Figure 2). The remaining three isolates (not shown) had multiple differences.

Using the secondary molecular genotyping techniques, we showed that all six isolates were different. We found that all strains but one had deletions in the DR region that included DR 24 (a common and perhaps original insertion site for IS6110). Only the strain from Liberia has spacer 24 in the DR region. This strain represented an exception in the zero-copy IS6110 strains.  However, the absence of spacer 24 is not an absolute indication of a zero-copy IS6110 strain. All Beijing strain families have a deletion that includes spacers 1–34, but they also have multiple IS6110 insertions (15 to 21) and some in the remaining DR region (18). 

Among the six zero-copy IS6110 strains, the three Vietnamese isolates had the same spoligotype and PGRS. By using VNTR genotyping we were able to differentiate these strains; two VNTR loci differentiated them. The importance of this finding is unknown. 

In comparing the six zero-copy IS6110 cases reported in this study with more recent data from the genotyping network and elsewhere, we identified 43 zero-copy IS6110 strains (Table). Most of these strains (35 [81%] of 43) originated from southern Asia. Fourteen of 32 spoligotyped strains are similar and have the same CDC designation. Additionally, eight of the strains are similar to CDC spoligotype 258, distinguished by the same absence of spacers 19–41. Most strains spoligotyped (29 [91%] of 32) have a deletion of the spacer 24 region. The other three isolates did have spacer 24, which cannot be explained without sequencing the DR region.

By using multiple genotyping methods, we confirmed the identification of zero-copy M. tuberculosis isolates. We further demonstrated that the six unrelated cases were caused by different M. tuberculosis strains. However, the close similarity of the Vietnamese genotypes implies an important geographic association. An optimal algorithm for evaluating zero band isolates is yet to be determined and should be based on evolving secondary methods.

Acknowledgments

We thank Alabama State Tuberculosis Laboratory, especially Donna Mulcahy and Nancy Robinson for preparing the strains for the study and William Bishai for providing pTBN12.

 Dr. Lok is a postdoctoral fellow in pulmonary diseases at the University of Alabama at Birmingham. His research interests include the molecular epidemiology of tuberculosis.

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