Molecular analysis of sarcoidosis tissues for Mycobacterium species DNA. (Research).We performed polymerase chain reaction polymerase chain reaction (pŏl`ĭmərās') (PCR), laboratory process in which a particular DNA segment from a mixture of DNA chains is rapidly replicated, producing a large, readily analyzed sample of a piece of DNA; the process is analysis, for Mycobacterium mycobacterium Any of the rod-shaped bacteria that make up the genus Mycobacterium. The two most important species cause tuberculosis and leprosy in humans; another species causes tuberculosis in both cattle and humans. species 16S rRNA, rpoB, and IS6110 sequences, on 25 tissue specimens from patients with sarcoidosis Sarcoidosis Definition Sarcoidosis is a disease which can affect many organs within the body. It causes the development of granulomas. Granulomas are masses resembling little tumors. They are made up of clumps of cells from the immune system. and on 25 control tissue specimens consisting of mediastinal mediastinal /me·di·as·ti·nal/ (-as-ti´n'l) of or pertaining to the mediastinum. mediastinal of or pertaining to the mediastinum. or cervical lymph nodes Cervical lymph nodes are lymph nodes found in the neck. Anterior cervical nodes The anterior cervical nodes are a group of nodes found on the anterior part of the neck. and lung biopsies. Mycobacterium species 16S rRNA sequences were amplified from 12 (48%) and rpoB sequences from 6 (24%) of the sarcoidosis specimens. In total, 16S rRNA or rpoB sequences were amplified from 15 sarcoidosis specimens (60%) but were not detected in any of the control tissues (p=0.00002, chi square chi square (kī), n a nonparametric statistic used with discrete data in the form of frequency count (nominal data) or percentages or proportions that can be reduced to frequencies. ). In three specimens, the sequences resembled Mycobacterium species other than M. tuberculosis M. tuberculosis, n the bacterium responsible for tuberculosis, generally a respiratory infection in man; nonrespiratory tuberculosis is considered an indicator disease for AIDS. See also tuberculosis. . All specimens with sequences consistent with M. tuberculosis were negative for IS6110. We provide evidence that one of a variety of Mycobacterium species, especially organisms resembling M. tuberculosis, is found in most patients with sarcoidosis. ********** Sarcoidosis is a multisystem inflammatory disease that mainly affects lymph nodes Lymph nodes Small, bean-shaped masses of tissue scattered along the lymphatic system that act as filters and immune monitors, removing fluids, bacteria, or cancer cells that travel through the lymph system. and pulmonary tissues and is characterized by noncaseating granulomata in affected organs (1). Although the cause of sarcoidosis remains unknown, several microorganisms have been proposed as possible etiologic agents, including bacteria (Borrelia burgdorferi Borrelia burg·dor·fe·ri n. A spirochete causing Lyme disease in humans. Borrelia burgdorferi The spirochete agent of Lyme disease, which contains several outer membrane proteins and a highly immunogenic flagellar , Proprionibacterium acnes, and Mycobacterium species) and viruses (Human herpesvirus herpesvirus, any of the family (Herpesviridae) of common DNA-containing viruses, many of which are associated with human disease. See cytomegalovirus; Epstein-Barr virus; herpes simplex; herpes zoster. 8, Epstein-Barr virus Epstein-Barr virus (EBV), herpesvirus that is the major cause of infectious mononucleosis and is associated with a number of cancers, particularly lymphomas in immunosuppressed persons, including persons with AIDS. , Cytomegalovirus cytomegalovirus (sī'təmĕg'əlōvī`rəs), member of the herpesvirus family that can cause serious complications in persons with weakened immune systems. , and Coxsackie B) (2). Metals (beryllium beryllium (bərĭl`ēəm) [from beryl ], metallic chemical element; symbol Be; at. no. 4; at. wt. 9.01218; m.p. about 1,278°C;; b.p. 2,970°C; (estimated); sp. gr. 1.85 at 20°C;; valence +2. and zirconium zirconium (zərkō`nēəm), metallic chemical element; symbol Zr; at. no. 40; at. wt. 91.22; m.p. about 1,852°C;; b.p. 4,377°C;; sp. gr. 6.5 at 20°C;; valence +2, +3, or +4. ), minerals (talc and clay), and organic substances (pine tree pollen) have also been proposed as etiologic agents (2). Efforts to identify an infectious agent infectious agent Pathogen, see there for sarcoidosis using methods such as histologic staining and routine microbial microbial pertaining to or emanating from a microbe. microbial digestion the breakdown of organic material, especially feedstuffs, by microbial organisms. culture have been unsuccessful. Polymerase chain reaction (PCR PCR polymerase chain reaction. PCR abbr. polymerase chain reaction Polymerase chain reaction (PCR) ) analysis for microbial DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. serves as an alternative method for identifying infectious agents. PCR was used to identify the etiologic agents of bacillary angiomatosis Bacillary Angiomatosis Definition A life-threatening but curable infection that causes an eruption of purple lesions on or under the skin that resemble Kaposi's sarcoma. (Bartonella henselae Bartonella henselae Rochalimaea henselae Infectious disease A slender, fastidious coccobacillary bacterium of the normal flora of cats associated with bacteremia, endocarditis, cat-scratch disease, bacillary angiomatosis, peliosis hepatis; it may affect ) (3) and Whipple's disease Whip·ple's disease n. A rare disease in which the intestinal wall is invaded by macrophages containing the remnants of bacteria and which is characterized by steatorrhea, generalized lymphadenopathy, arthritis, fever, and cough. (Tropheryma whippelii Tropheryma whippelii The causative bacillus of Whipple's disease, and some cases of uveitis Diagnosis Suspected is based on evidence with EM; confirmed by PCR to detect 16S ribosomal RNA gene–rDNA sequences of T whippelii; T whippelii ) (4). Because of the substantial pathologic (5), immunologic (6), epidemiologic (7), and clinical similarities (8,9) between sarcoidosis and infections caused by Mycobacterium species (particularly tuberculosis), we analyzed tissue specimens from patients with sarcoidosis for evidence of mycobacterial mycobacterial emanating from or pertaining to mycobacterium. mycobacterial granuloma may be caused by Mycobacterium tuberculosis (see cutaneous tuberculosis), M. genes. The results of previous studies have been inconclusive; some investigators were unable to demonstrate mycobacterial DNA in sarcoid sarcoid /sar·coid/ (sahr´koid) 1. sarcoidosis. 2. a sarcoma-like tumor. 3. fleshlike. sar·coid adj. Of or resembling flesh. n. 1. lesions (10,11), whereas others have amplified mycobacterial DNA of different species (12,13). We examined sarcoidosis and control paraffin-embedded pulmonary, mediastinal, and cervical tissue specimens for Mycobacterium species 16S rRNA, rpoB, and IS6110 sequences. Materials and Methods Patients and Samples For this study, we selected paraffin-embedded tissue specimens from patients who had had mediastinal or cervical lymph node lymph node Small, rounded mass of lymphoid tissue contained in connective tissue. They occur all along lymphatic vessels, with clusters in certain areas (e.g., neck, groin, armpits). resection from 1991 to 2001. Specimens from 44 patients with sarcoidosis and 57 controls were included. Patients were included for further study if they met the pathologic and clinical features described and if the specimens, after processing and DNA extraction, were positive for human [beta]-actin with PCR analysis. We were unable to retrieve purified protein derivative purified protein derivative see purified protein derivative of tuberculin. status on a systematic basis. Based on these criteria, 25 control and 25 sarcoidosis specimens were further analyzed. For inclusion in this study, the following criteria was used for patients with sarcoidosis: 1) clinical features had to be consistent with sarcoidosis (i.e., acute respiratory illness accompanied by erythema nodosum Erythema Nodosum Definition Erythema nodosum is a skin disorder characterized by painful red nodules appearing mostly on the shins. Description , hilar hi·lar adj. Of or relating to a hilum. adenopathy and arthritis [Lofgren's syndrome], or indolent indolent /in·do·lent/ (in´dah-lint) 1. causing little pain. 2. slow growing. in·do·lent adj. 1. Disinclined to exert oneself; habitually lazy. 2. progressive pulmonary decompensation decompensation /de·com·pen·sa·tion/ (de?kom-pen-sa´shun) 1. inability of the heart to maintain adequate circulation, marked by dyspnea, venous engorgement, and edema. 2. associated with radiographic radiographic (rā´dēōgraf´ik), adj relating to the process of radiography, the finished product, or its use. findings, such as hilar adenopathy, reticulonodular infiltrates, or pulmonary fibrosis Pulmonary Fibrosis Definition Pulmonary fibrosis is scarring in the lungs. Description Pulmonary fibrosis develops when the alveoli, tiny air sacs that transfer oxygen to the blood, become damaged and inflamed. ); 2) histopathologic features had to be consistent with sarcoidosis (i.e., specimens from each patient had to have confluent con·flu·ent adj. 1. Flowing together; blended into one. 2. Merging or running together so as to form a mass, as sores in a rash. noncaseating granulomas, well circumscribed circumscribed /cir·cum·scribed/ (serk´um-skribd) bounded or limited; confined to a limited space. cir·cum·scribed adj. Bounded by a line; limited or confined. within the surrounding tissue with a variable amount of peripheral lymphocytic infiltration [5]); 3) known microbial causes for granulomata had to be excluded (i.e., specimens were negative for microorganisms by hematoxylin hematoxylin /he·ma·tox·y·lin/ (he?mah-tok´si-lin) an acid coloring matter from the heartwood of Haematoxylon campechianum; used as a histologic stain and also as an indicator. and eosin eosin /eo·sin/ (e´o-sin) any of a class of rose-colored stains or dyes, all being bromine derivatives of fluorescein; eosin Y, the sodium salt of tetrabromofluorescein, is much used in histologic and laboratory procedures. (H&E), fungal, acid fast bacilli bacilli /ba·cil·li/ (bah-sil´i) plural of bacillus. bacilli see bacillus. (AFB AFB abbr. acid-fast bacillus AFB Acid-fast bacillus, also 1. Aflatoxin B 2. Aorto-femoral bypass ), and auramine-O stains and on routine bacterial, fungal, and AFB cultures). In each case, histopathologic specimens were independently reviewed by two pathologists. Control lymph node specimens were selected from patients who had undergone mediastinoscopy or cervical node biopsy during the same period. In each case, a definitive diagnosis other than sarcoidosis was made. Control patients were selected from patients for whom the final diagnoses were fungal infection fungal infection, infection caused by a fungus (see Fungi), some affecting animals, others plants. Fungal Infections of Human and Animals , lymphoma, and primary or metastatic Metastatic The term used to describe a secondary cancer, or one that has spread from one area of the body to another. Mentioned in: Coagulation Disorders metastatic pertaining to or of the nature of a metastasis. lung malignancies (Table 1). DNA Extraction For each patient enrolled in the study, the original paraffin-embedded tissue block was retrieved from the archives, and eleven 10-[micro]m sections were cut from each. One section was stained with H&E for microscopic examination, four sections were used for extraction of DNA, and the remaining six sections were stored for future analysis. The specimens were randomly processed for slide preparation, and the microtome microtome /mi·cro·tome/ (mi´krah-tom) an instrument for cutting thin sections for microscopic study. mi·cro·tome n. blade was changed between each tissue block. For each section from patients with sarcoidosis and for the control specimens with the granulomata, granulomata were microdissected and extracted by using disposable surgical blades. For those control specimens without granulomata, all tissue from the four sections was used for DNA extraction. For all specimens, DNA was extracted with the Qiagen DNAeasy extraction kit (Qiagen, Valencia, CA) according to the manufacturer's instructions, except that 60 [micro]L of proteinase proteinase /pro·tein·ase/ (pro´ten-as?) endopeptidase. pro·tein·ase n. A protease that begins the hydrolytic breakdown of proteins usually by splitting them into polypeptide chains. K was used at a concentration of 20 mg/mL. Tissue dissection and DNA preparation were performed in a dedicated clean room, which was separate from the rooms used for PCR analysis and sequencing. The extracted DNA was stored at -20[degrees]C. Groups of tissue specimens from patients with sarcoidosis and controls were processed in parallel during all steps of the procedure, including extraction of the DNA, amplification and detection of mycobacterial DNA, and sequence analysis. PCR Analysis for 168 rRNA, rpoB, and 186110 Before PCR amplification, to ensure that the extracted DNA was of proper quality, we used PCR to verify that DNA sequences encoding human [beta]-actin could be amplified. The primers used were 5'ATCATGTTTGAGACCTTCAAC3' (forward primer) and 5'CAGGAAGGAAGGCTGGAAGAG3' (reverse primer). The PCR conditions were 35 cycles of amplification carried out in a DNA Thermal Cycler 480 (Perkin-Elmer, Wellesley, MA); each cycle consisted of 1 rain of denaturing at 94[degrees]C, 1 min of annealing annealing (ənēl`ĭng), process in which glass, metals, and other materials are treated to render them less brittle and more workable. at 54[degrees]C, and 1 min of extension at 72[degrees]C (14). As required, all 50 tissue specimens yielded human [beta]-actin amplicons and were tested further for the presence of bacterial DNA. For amplification of 16S rRNA sequences, a nested PCR analysis was performed. The primers FO16S, 5'GATAA GCCTGGGAAACTGGGTC3' and RO16S, 5'TTCTCCACCTACCG TCAATCCG3' were selected to amplify a 344-bp fragment of the 5' region (nt 134-477) of mycobacterial 16S rRNA. Primers FI16S (5'CATGTCTTGTGGTGGAAAG CG3') and RI16S (5'TACCGTC AATCCGAGAGAACCC3') were selected as nested primers to amplify a 288-bp fragment (nt 181-468). The PCR conditions for both sets of primers were as follows: 5 min of denaturing at 94[degrees]C, followed by 35 cycles of amplification, consisting of 1 min of denaturing at 94[degrees]C, 1 min of annealing at 58[degrees]C, and 1 min of extension at 72[degrees]C. At the end of the 35 cycles, a final extension cycle of 7 minutes at 72[degrees]C was performed. For amplification of rpoB sequences, a nested PCR also was performed. The primers FOrpoB (5'GCAGACGC TGTTGGAAAACTTG3') and ROrpoB, (5'TGTTCTGGTCC ATGAATTGGCTC3') were selected to amplify a 455-bp fragment of the [beta] subunit (nt 1,940-2,394) of the M. tuberculosis RNA polymerase RNA polymerase n. A polymerase that catalyzes the synthesis of RNA from a DNA or RNA template. gene. The inner primers were designed as previously described and used in a nested fashion (nt 1,965-2,324) to amplify a 360-bp product (15). The PCR conditions were as described previously for 16S rRNA. For amplification of IS6110 sequences, PCR analysis included the use of primers IS 1 (5'CCTGCGAGCGTAGGCG TCGG3') and IS2 (5'CTCGTCCAGCGCCGCTTCGG3'), designed to amplify a 123-bp fragment (nt 1,510-1,632) of the M. tuberculosis IS6110 element (16). The assay used the same conditions as described previously, with the exception that the PCR analysis included 30 rather than 25 cycles. Negative and positive controls were run in parallel with each PCR assay. We used genomic DNA extracted from M. tuberculosis strain H37rv as positive controls, and DNA extracted from a paraffin-embedded tissue biopsy from an AIDS patient with ileocecal tuberculosis as positive controls. We included the following as negative controls in each PCR reaction: DNA extracted from nonsarcoid paraffin-embedded tissue, PCR master mix inoculated with 5 [micro]L of sterile water, and PCR master mix alone. The DNA extraction was performed in the same manner as described for the sarcoid and control specimens. Determination of DNA Sequence of Amplified Products The PCR products were purified with the Qiagen QIAquick PCR purification kit (Qiagen, alencia, CA) and sequenced directly on both strands in the Vanderbilt Cancer Center Core Sequencing Laboratory. In cases in which the signal was ambiguous, PCR products were cloned into the plasmid vector system, pGEM T-Easy (Promega, Madison, WI), and the nucleotide sequences were then determined. Alignments of the 16S rRNA, rpoB, and IS6110 sequences were performed with the NCBI NCBI National Center for Biotechnology Information (NIH) NCBI National Coalition Building Institute NCBI National Council for the Blind of Ireland (Dublin, Ireland) BLAST program. Statistical evaluation of significance was determined by using chi-square analysis or Fisher's exact test Fisher's exact test a statistical test for association in a two-by-two table based on the exact hypergeometric distribution of the frequencies within the table. , depending upon anticipated cell size. Sequences were aligned with ClustalW and subjected to phylogenetic phy·lo·ge·net·ic adj. 1. Of or relating to phylogeny or phylogenetics. 2. Relating to or based on evolutionary development or history. analysis with HKY HKY Hickory, NC, USA (Airport Code) 85 distance matrices with Paup 4.068 (Sinauer Associates, Sunderland, MA). Results Patient and Specimen Characteristics Of the 25 patients with sarcoidosis, 12% were African American African American Multiculture A person having origins in any of the black racial groups of Africa. See Race. and 88% Caucasian; 36% were men, and 64% were <50 years of age. No specimens were obtained from persons <18 years of age (Table 1). The control population was 20% African American and 80% Caucasian; 68% were men. Most (76%) of the control patients were >50 years of age; the age and sex of the control patients reflect the patient population undergoing mediastinoscopy to obtain a tissue diagnosis for probable malignancy. The control population consisted of patients with lung cancer lung cancer, cancer that originates in the tissues of the lungs. Lung cancer is the leading cause of cancer death in the United States in both men and women. Like other cancers, lung cancer occurs after repeated insults to the genetic material of the cell. (72%), chronic fungal infections (16%), or lymphoma (12%) (Table 1). Mediastinal lymph nodes were the source of specimens from 88% and 84% of the sarcoid and control patients, respectively. The remaining specimens from each group were obtained from either pulmonary or cervical lymph node biopsies. Granulomas were present in all of the sarcoidosis tissue specimens and in 7 of the 25 control specimens. PCR Assay Sensitivities The sensitivity of the PCR assay for each gene was determined by PCR analysis of serially diluted genomic DNA from M. tuberculosis strain H37rv, ranging from 5 ng to 0.05 fg per [micro]L. One M. tuberculosis genome is estimated to have a mass of 5 fg (17). For PCR analyses of 16S rRNA, rpoB, and IS6110, we consistently achieved a sensitivity of 1-2 gene copies in each assay. 16S rRNA PCR of Tissue Specimens In the PCR for 16S rRNA sequences (Table 2), 12 (48%) of the 25 sarcoidosis specimens tested positive compared to none of 25 of the control specimens (p=0.0003, chi square). Sequence analysis of the PCR products from the sarcoidosis specimens showed that 8 of the 12 had 100% positional identity with M. tuberculosis, and 1 possessed 99% positional identity with M. tuberculosis (patient 15). Sequencing of the 16S PCR product of patient 15 showed a C [right arrow] T substitution at position 289 and an A [right arrow] G substitution at position 355 (based on the M. tuberculosis 16S rRNA sequence, GenBank accession nos. Z83862.1, AJ131120.1, X52917.1, and X58890.1). Three other sequences were found (in patients 7, 19, and 24) that most closely resembled other Mycobacterium species. The amplicon sequence from patient 7 possessed an A [right arrow] G substitution at position 299 and a C [right arrow] A substitution at position 380, yielding 99% positional identity with M. kansasii. Notably the sequences of M. kansasii, M. avium, M. visibilis, and M. paratuberculosis are identical within this region; therefore, distinguishing between these species is not possible (18). The amplicon sequence from patient 19 contained a T [right arrow] C substitution at position 434, yielding 99% positional identity with M. gordonae. The amplicon sequence from patient 24 contained 100% positional identity with M. gordonae and M. bohemicum (19). The phylogenetic relationships of the mycobacterial sequences are shown in the Figure and are deposited in GenBank (accession nos. AF468214, AF468215, and AF468216). PCR of Tissue Specimens with Other Mycobacterial Primers With the rpoB PCR, 6 (24%) of the 25 specimens from sarcoidosis patients yielded a product of 360 bp, which by sequence analysis in each case was most consistent with M. tuberculosis. Five sequences amplified from sarcoidosis specimens had 98%-100% positional identity with M. tuberculosis (patients 1, 3, 8, 14, and 24), whereas one had 95% positional identity (patient 16) (Table 2). The difference in the rate of finding M. tuberculosis rpoB sequences (24% in the sarcoidosis specimens and none in the control specimens) was also significant (p=0.02, Fisher's exact test). In total, 15 (60%) of the sarcoidosis specimens had either Mycobacterium 16S rRNA or rpoB sequences compared with none of the control specimens (p=0.00002, chi square). Mycobacterial 16S rRNA and rpoB fragments were amplified from 3 (12%) of the 25 sarcoidosis specimens (patients 1, 14, and 24). Patients 1 and 14 possessed sequences that had 100% positional identity with M. tuberculosis 16S rRNA and 98%-99% positional identity with M. tuberculosis rpoB DNA. The products amplified from patient 24 possessed 100% positional identity with M. gordonae 16S rRNA and 99% positional identity with M. tuberculosis rpoB DNA. In the region amplified with our 16S primers, a difference of 14 nt existed between the 16S rRNA of M. tuberculosis and M. gordonae. In the region amplified by using rpoB primers, a difference of 39 nt existed between rpoB of M. tuberculosis and M. gordonae. None of the sarcoidosis or control patient tissue specimens yielded IS6110 amplicons (Table 2). In contrast, IS6110 products were consistently found in the positive controls, genomic DNA from M. tuberculosis H37rv, and DNA extracted from a paraffin-embedded tissue biopsy of an AIDS patient with ileocecal tuberculosis. Both positive controls were positive in the 16S rRNA, rpoB, and IS6110 PCR assays, and sequence analysis of the products indicated 100% homology with M. tuberculosis. The negative controls were consistently negative. Discussion For this study, we chose patients whose cases were consistent with sarcoidosis or in whom an alternative diagnosis was made conclusively. We chose this stringent design so that no borderline tissues were examined. Many cases of disease eventually diagnosed as sarcoidosis have atypical findings. If our present observations are confirmed, such cases will be important for future analyses. We found evidence of mycobacterial DNA in the granulomas of 24% of sarcoidosis specimens when assessing for rpoB, 48% in the same population when assessing for 16S rRNA; in total, 60% were positive for either. We acknowledge the limitations of studying archival tissue and the possibility of contamination; however, control tissues did not demonstrate positive results, making contamination less likely. Earlier studies have identified the presence of mycobacterial DNA in sarcoidosis tissue specimens with 30%-50% prevalence (12,13,20). Instead of a single organism being present, we provide evidence for a heterogenous (spelling) heterogenous - It's spelled heterogeneous. population of Mycobacterium species in the sarcoidosis tissue specimens studied. Although we found evidence of organisms resembling M. tuberculosis, M. gordonae, and M. kansasii, other studies also have identified M. avium sequences (12,13). We also provide DNA sequence evidence for novel mycobacteria mycobacteria members of the genus Mycobacterium. anonymous mycobacteria see opportunist (atypical) mycobacteria (below). nontubercular mycobacteria see opportunist (atypical) mycobacteria (below). in patient 15. Although most DNA sequences from the study patients most closely resemble M. tuberculosis, sequences resembling other mycobacterial species also were identified (Table 2, Figure). In several previous studies, nontuberculosis mycobacteria also have been reported (13). One novel sequence is most closely related to 16S rDNA from M. tuberculosis, a known pulmonary pathogen, rather than to sequences from other mycobacterial species of lesser virulence. The consistent presence of two single polymorphisms in the same location in the novel sequence suggests a true polymorphism rather than an error introduced by Taq PCR. Moreover, the novel sequence was consistently absent from water, non-sarcoid paraffin-embedded tissue, and M. tuberculosis DNA controls. Synonymous substitutions in the M. tuberculosis genome are relatively rare, although genomic variations have been found in genes associated with antibiotic resistance antibiotic resistance, n the ability of certain strains of microorganisms to develop resistance to antibiotics. antibiotic resistance (21). The DNA with the polymorphism suggests that a variant of M. tuberculosis, or a closely related novel mycobacterium, may be present in the sarcoidosis specimen. The presence of M. tuberculosis DNA in 48% of sarcoidosis specimens is notable because clear clinical connections between sarcoidosis and tuberculosis have been made. On occasion, patients with documented tuberculosis develop sarcoidosis while on antituberculous treatment or vice versa (22-24). Mycobacterial DNA in sarcoidosis specimens may explain the clinical correlation between sarcoidosis and tuberculosis. That patients have developed sarcoidosis while on antituberculous therapy suggests that in those patients M. tuberculosis was not the etiologic agent of sarcoidosis. That 60% of the specimens we examined showed mycobacterial DNA agrees with certain previous studies (12,13), but other studies were negative for mycobacterial DNA (10,11). One possible explanation for these discordant results is that sarcoidosis represents one group of host responses to infectious agents of which mycobacteria represent the largest associated group. Alternatively, Mycobacterium species are present in many of the, lesions but at extremely low levels, on either side of the threshold of detection. Such a hypothesis of small numbers of organisms provoking an intense inflammatory response, analogous to tuberculoid leprosy (25), could explain why organisms cannot be detected except by ultrasensitive methods. Yet another alternative explanation was our observation of degradation of the mycobacterial signal in the total DNA extract. We observed that mycobacterial DNA could be amplified from the positive specimens consistently over a 6-8 month period if the original DNA extract was maintained at--20[degrees]C. After this time period, fresh DNA extractions were necessary to demonstrate the presence of mycobacterial DNA. The original specimens, in which the mycobacterial DNA could no longer be amplified, remained positive for human [beta]-actin by PCR analysis, although the band was weaker, suggesting either that the eukaryotic eukaryotic /eu·kary·ot·ic/ (u?kar-e-ot´ik) pertaining to a eukaryon or to a eukaryote. eukaryotic pertaining to eukaryosis. eukaryotic cells see cell. DNA degraded more slowly than prokaryotic pro·kar·y·ote also pro·car·y·ote n. An organism of the kingdom Monera (or Prokaryotae), comprising the bacteria and cyanobacteria, characterized by the absence of a distinct, membrane-bound nucleus or membrane-bound organelles, and by DNA that DNA or that more signal was originally present. This degradation occurred despite minimizing freeze-thaws of extracted DNA and maintaining the DNA at -20[degrees]C. Our observation suggests that isolation of mycobacterial DNA from sarcoidosis specimens is best achieved by performing PCR analysis on fresh DNA extractions, which may help explain why other investigators had negative findings. Based on these observations, we examined whether M. tuberculosis DNA was present in the sarcoid granuloma granuloma /gran·u·lo·ma/ (gran?u-lo´mah) pl. granulomas, granulo´mata an imprecise term for (1) any small nodular delimited aggregation of mononuclear inflammatory cells, or (2) such a collection of modified macrophages by testing for the presence of IS6110. PCR analysis for IS6110 is useful, since IS6110 is typically present in 1-25 copies in members of the M. tuberculosis complex. M. bovis BCG BCG bacille Calmette-Guérin. BCG abbr. 1. bacillus Calmette-Guérin 2. ballistocardiogram BCG, n.pr See bacille Calmette-Guórin. has only a single of copy of IS6110, whereas the higher copy numbers are typically found in M. tuberculosis isolates (26). We found no evidence of IS6110 DNA in our sarcoidosis or control tissue specimens. Several possible explanations exist for the presence of mycobacterial 16S rRNA and rpoB, and the absence of IS6110 in the sarcoid specimens, although these three amplicons were consistently present in our positive controls. First, our assay for IS6110 may not have been sufficiently sensitive to detect the very low numbers of M. tuberculosis genomes in the sarcoidosis tissue specimens. In serial dilution studies, the assay was sensitive enough to detect one bacterial genome, comparable to results for the nested PCRs for 16S and rpoB. However, correlating the sensitivity of DNA extracted from bacterial culture to DNA extracted from formalin-fixed, paraffin-embedded tissue is not possible. Other laboratories that reported an assay sensitivity of 1-2 genome copies for IS6110 in sarcoidosis tissue extract were also unable to detect any IS6110 (11,27-29), which was consistent with our results. Studies assessing for IS6110 reflect a substantial portion of the literature that does not support the presence of mycobacterial DNA in the sarcoidosis tissue specimens (11,27,28,30). A second possibility is that M. tuberculosis is present but the strains do not contain IS6110, since strains that possess one copy or no copies of IS6110 have been reported (31,32). In the United States, all of approximately 14,000 strains of M. tuberculosis tested have been shown to possess IS6110; some in low-copy number (33). Therefore, this scenario seems unlikely. A third explanation is that while the agent we found associated with sarcoidosis has a close genetic relationship with M. tuberculosis, it is not M. tuberculosis. The genes for 16S and 23S are particularly suitable as targets for identifying microorganisms, since they are both well conserved and show variation indicative of their evolution and interrelationship in·ter·re·late tr. & intr.v. in·ter·re·lat·ed, in·ter·re·lat·ing, in·ter·re·lates To place in or come into mutual relationship. in with other organisms (34). This genetic variation is the basis for identifying the species of microorganisms in a particular genus, as this genetic variation is a constant property. Other members of the M. tuberculosis-complex (M. tuberculosis BCG, M. bovis, M. microti, and M. africanum) have 100% 16S and rpoB homology with M. tuberculosis but belong to different species; these strains are usually differentiated from M. tuberculosis by biochemical and clinical features. Although we could not attempt isolation of microorganisms from the formalin-fixed, paraffin-embedded specimens, future studies targeted to mycobacteria would be especially useful in confirming our observations and in characterizing any association with sarcoidosis. We have found evidence for mycobacterial 16S rRNA and rpoB sequences in sarcoidosis tissue specimens but not in control tissue specimens. Upon sequence analysis, the products were most consistent with M. tuberculosis, but IS6110 could not be detected from these species. We also provide evidence of the presence of a heterogeneous mycobacterial population, including organisms highly related to M. tuberculosis, M. gordonae, and M kansasii. This heterogeneous population was found in individual sarcoidosis samples and, in one case, in the same sample (patient 24). These findings suggest that while M. tuberculosis and other Mycobacterium species may not be the sole microbial agents present in sarcoidosis tissues, they are commonly present and may play important roles. Further investigation into their presence and any putative etiologic agent is warranted.
Table 1. Demographic and pathologic information for sarcoidosis and
control tissue specimens (a)
Patient Age (yrs)/sex Race Source of specimen
1 61/M C Lung
2 60/F C Cervical node
3 43/F C Mediastinum
4 55/F C Mediastinum
5 42/M AA Mediastinum
6 54/F C Mediastinum
7 48/F C Mediastinum
8 34/M C Mediastinum
9 72/F AA Mediastinum
10 42/F C Mediastinum
11 42/F C Mediastinum
12 68/F C Mediastinum
13 37/F C Mediastinum
14 45/F C Mediastinum
15 46/F C Mediastinum
16 38/M C Mediastinum
17 33/F C Mediastinum
18 26/M C Mediastinum
19 55/F AA Mediastinum
20 31/M C Mediastinum
21 42/M C Lung
22 42/F C Mediastinum
23 38/M C Mediastinum
24 54/F C Mediastinum
25 78/M C Mediastinum
26 33/M AA Lung
27 70/F C Lung
28 73/M C Mediastinum
29 56/F C Mediastinum
30 24/M C Lung
31 75/M C Lung
32 32/M AA Mediastinum
33 41/F C Mediastinum
34 74/F C Mediastinum
35 72/F C Mediastinum
36 77/M C Mediastinum
37 72/M AA Mediastinum
38 78/F C Mediastinum
39 72/M C Mediastinum
40 52/F AA Mediastinum
41 52/F C Mediastinum
42 73/M C Mediastinum
43 18/M AA Mediastinum
44 47/M C Mediastinum
45 74/M C Mediastinum
46 76/M C Mediastinum
47 75/M C Mediastinum
48 60/M C Mediastinum
49 73/M C Mediastinum
50 85/M C Mediastinum
51 40/M AA Ileum
Patient Pathologic diagnosis Presence of granuloma
1 Sarcoidosis Yes
2 Sarcoidosis Yes
3 Sarcoidosis Yes
4 Sarcoidosis Yes
5 Sarcoidosis Yes
6 Sarcoidosis Yes
7 Sarcoidosis Yes
8 Sarcoidosis Yes
9 Sarcoidosis Yes
10 Sarcoidosis Yes
11 Sarcoidosls Yes
12 Sarcoidosis Yes
13 Sarcoidosis Yes
14 Sarcoidosis Yes
15 Sarcoidosis Yes
16 Sarcoidosis Yes
17 Sarcoidosis Yes
18 Sarcoidosis Yes
19 Sarcoidosis Yes
20 Sarcoidosis Yes
21 Sarcoidosis Yes
22 Sarcoidosis Yes
23 Sarcoidosis Yes
24 Sarcoidosis Yes
25 Sarcoidosis Yes
26 Hodgkin's disease No
27 Histoplasmosis Yes
28 Mesothelioma No
29 Adenocarcinoma No
30 Cryptococcus Yes
31 Renal cell cancer No
32 Coccidiomycosis Yes
33 Breast cancer No
34 Adenocarcinoma No
35 Large-cell cancer No
36 Large-cell cancer No
37 Large-cell cancer Yes
38 Adenocarcinoma No
39 Squamous cell cancer No
40 Adenocarcinoma Yes
41 Breast cancer Yes
42 Adenocarcinoma Yes
43 Histoplasmosis No
44 Hodgkin's lymphoma No
45 Large-cell lymphoma No
46 Adenocarcinoma No
47 Small-cell cancer No
48 Adenocarcinoma No
49 Adenocarcinoma No
50 Lymphoma No
51 Tuberculosis No
(a) F, female, M, male; C, Caucasian; AA, African-American.
Table 2. Analysis of sarcoidosis and control tissue specimens for
Mycobacterium 16SrRNA, rpoB, and IS6110 (a)
Sarcoidosis
patient 16S rRNA rpoB IS6110
1 M. tuberculosis M. tuberculosis --
2 M. tuberculosis - -
3 - M. tuberculosis -
4 M. tuberculosis - -
5 M. tuberculosis - -
6 - - -
7 M. kansasii - -
8 - M. tuberculosis -
9 M. tuberculosis - -
10 - - -
11 M. tuberculosis - -
12 - - -
13 - - -
14 M. tuberculosis M. tuberculosis -
15 NM - -
16 - M. tuberculosis -
17 - - -
18 M. tuberculosis - -
19 M. gordonae - -
20 - - -
21 - - -
22 - - -
23 - - -
24 M. gordonae M. tuberculosis -
25 - - -
Control patient 16S rRNA rpoB IS6110
26 - - -
27 - - -
28 - - -
29 - - -
30 - - -
31 - - -
32 - - -
33 - - -
34 - - -
35 - - -
36 - - -
37 - - -
38 - - -
39 - - -
40 - - -
41 - - -
42 - - -
43 - - -
44 - - -
45 - - -
46 - - -
47 - - -
48 - - -
49 - - -
50 - - -
51 M. tuberculosis M. tuberculosis M. tuberculosis
H37rv M. tuberculosis M. tuberculosis M. tuberculosis
(a) NM, novel mycobacterium, resembling M. tuberculosis; H37rv, M.
tuberculosis; -, indicates a negative result.
Acknowledgments We thank David Relman for guidance throughout the project, Colorado State University Colorado State University, at Fort Collins; land-grant with state and federal support; chartered 1870, opened 1879 as an agricultural college, assumed present name in 1957. There is a veterinary teaching hospital, an agricultural campus, and a research campus. (NIAID NIAID National Institute of Allergy and Infectious Diseases. NO1 AI-75320) for supplying our laboratory with the Mycobacterium tuberculosis strain H37rv, and Edward McDonald for providing paraffin-embedded lymph node biopsy specimens. References (1.) Crystal RG, Bitterman PB, Rennard SI, Hance A J, Keogh BA. Interstitial lung diseases of unknown cause: disorders characterized by chronic inflammation of the lower respiratory tract Noun 1. lower respiratory tract - the bronchi and lungs lung - either of two saclike respiratory organs in the chest of vertebrates; serves to remove carbon dioxide and provide oxygen to the blood . N Engl J Med 1984;310:154-66. (2.) American Thoracic Society American Thoracic Society (ATS ), established in 1905, is an independently incorporated, international, educational and scientific society, serving its 18,000 members world-wide who are dedicated in respiratory and critical care medicine. (ATS), the European Respiratory Society (ERS ERS, n.pr See extended rotated side-bent. ) and the World Association of sarcoidosis and Other Granulomatous granulomatous /gran·u·lom·a·tous/ (-lom´ah-tus) containing granulomas. Granulomatous Resembling a tumor made of granular material. Disorders (WASOG WASOG World Association of Sarcoidosis and Other Granulomatous Diseases (Greece) ). Statement on sarcoidosis. Am J Respir Crit Care Med 1999;160:736-55. (3.) Relman DA, Loutit JS, Schmidt TM, Falkow S, Tompkins LS. The agent of bacillary angiomatosis. An approach to the identification of uncultured pathogens. N Engl J Med 1990;323:1573-80. (4.) Relman DA, Schmidt TM, MacDermott RP, Falkow S. Identification of the uncultured bacillus bacillus (bəsĭl`əs), any rod-shaped bacterium or, more particularly, a rod-shaped bacterium of the genus Bacillus. Some bacterium in the genus cause disease, for example B. of Whipple's disease. N Engl J Med 1992;327:293-301. (5.) Scadding JG, Mitchell DN. Sarcoidosis. 2nd ed. London: Chapman and Hall Chapman and Hall was a British publishing house, founded in the first half of the 19th century by Edward Chapman and William Hall. 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Tubercle tubercle (t  `bərkyl') [Lat.,=little swelling], small, usually solid, nodule or prominence. 1965;46:412-6.(8.) Mitchell DN, Rees RJW RJW Russo-Japanese War . Some diseases of possible mycobacterial aetiology aetiology see etiology. . In: Ratledge C, Stanford J, editors. The biology of mycobacteria. London: Academic Press; 1982. p. 525-36. (9.) Rook GA, Stanford JL. Slow bacterial infections or autoimmunity? Immunol Today 1992; 13:160-4. (10.) Richter E, Greinert U, Kirsten D. Assessment of mycobacterial DNA in cells and tissues of mycobacterial and sarcoid lesions. Am J Respir Crit Care Med 1996;153:375-80. (11.) Bocart D, Lecossier D, de Lassence A, Valeyre D, Battesti JP, Hance A J. A search for mycobacterial DNA in granulomatous tissues from patients with sarcoidosis using the polymerase chain reaction. Am Rev Respir Dis 1992;145:1142-8. (12.) Popper HH, Klemen H, Hoefler G, Winter E. Presence of mycobacterial DNA in sarcoidosis. Hum Pathol 1997;28:796-800. (13.) Li N, Bajoghi A, Kubba A, Bhawan J. Identification of mycobacterial DNA in cutaneous cutaneous /cu·ta·ne·ous/ (ku-ta´ne-us) pertaining to the skin. cu·ta·ne·ous adj. Of, relating to, or affecting the skin. Cutaneous Pertaining to the skin. lesions of sarcoidosis. J Cutan Pathol 1999;26:271-8. (14.) Hall BL, Finn OJ. PCR-based analysis of the T-cell receptor V beta multigene family: experimental parameters affecting its validity. Biotechniques 1992;13:248-57. (15.) Kim B J, Lee SH, Lyu MA, Kim S J, Bai GH, Chae GT, et al. Identification of mycobacterial species by comparative sequence analysis of the RNA polymerase gene (rpoB). J Clin Microbiol 1999;37:1714-20. (16.) Eisenach KD, Cave MD, Bates Bates , Katherine Lee 1859-1929. American educator and writer best known for her poem "America the Beautiful," written in 1893 and revised in 1904 and 1911. JH, Crawford JT. Polymerase chain reaction amplification of a repetitive DNA sequence specific for Mycobacterium tuberculosis. J Infect Dis 1990;161:977-81. (17.) Del Portillo P, Munillo LA, Patarroyo ME. Amplification of a species-specific DNA fragment of Mycobacterium tuberculosis and its possible use in diagnosis. J Clin Microbiol 1991;29:2163-8. (18.) Edwards U, Rogall T, Blocker H, Emde M, Bottger EC. Isolation and direct complete nucleotide determination of entire genes. Characterization of a gene coding for 16S ribosomal RNA. Nucleic Acid Res 1989;17:7843-53. (19.) Rogall T, Wolters J, Flohr T, Bottger EC. Towards a phylogeny and definition of species at the molecular level within the genus Mycobacterium. Int J Syst Bacteriol 1990;40:323-30. (20.) El-Zaatari FA, Naser SA, Markesich DC, Kalter DC, Engstand L, Graham DY. Identification of Mycobacterium avium complex Mycobacterium avium complex (MAC) is a group of genetically-related bacteria belonging to the genus Mycobacterium. It includes Mycobacterium avium subspecies avium (MAA), Mycobacterium avium subspecies hominis (MAH), and in sarcoidosis. J Clin Microbiol 1996;34:2240-5. (21.) Sreevatsan S, Pan X, Stockbauer KE, Connell ND, Kreiswirth BN, Whittam TS, et al. Restricted structural gene polymorphism in the Mycobacterium tuberculosis complex indicates evolutionarily recent global dissimenation. Proc Natl Acad Sci U S A 1997;94:9869-74. (22.) Wong CF, Yew WW, Wong PC, Lee J. A case of concomitant tuberculosis and sarcoidosis with mycobacterial DNA present in the sarcoid lesion. Chest 1998;114:626-9. (23.) Emerson PA, Young FH. Sarcoidosis following tuberculosis. Tubercle 1956;4:116-9. (24.) Kent DC, Houk VN, Elliott RC, Sokolowski JW, Baker JH, Sorensen K. The definitive evaluation of sarcoidosis. American Review of Respiratory Diseases 1970;101:721-7. (25.) Sieling RA, Modlin RL. Cytokine Cytokine Any of a group of soluble proteins that are released by a cell to send messages which are delivered to the same cell (autocrine), an adjacent cell (paracrine), or a distant cell (endocrine). patterns at the site of mycobacterial infection. Immunobiology 1994;191:378-87. (26.) van Soolingen D, Hermans PWM (Pulse Width Modulation) A modulation technique that generates variable-width pulses to represent the amplitude of an analog input signal. Like its fixed-width pulse density modulation (PDM) cousin, the output switching transistor is on more of the time for a , De Haas PEW, Soil DR, van Embden JDA JDA Japan Defense Agency JDA Joint Development Agreement JDA Janne da Arc (band) JDA Joint Duty Assignment JDA Jerusalem Development Authority JDA Jovian Detention Authority (gaming) . Comparison of various repetitive DNA elements as genetic markers for strain differentiation and epidemiology of Mycobacterium tuberculosis. J Clin Microbiol 1991;29:2578-86. (27.) Wilsher ML, Menzies RE, Croxson MC. Mycobacterium tuberculosis DNA in tissues affected by sarcoidosis. Thorax thorax, body division found in certain animals. In humans and other mammals it lies between the neck and abdomen and is also called the chest. The skeletal frame of the thorax is formed by the sternum (breastbone) and ribs in front and the dorsal vertebrae in back. 1998;53:871-4. (28.) Vokurka M, Lecossier D, du Bois RM, Wallaert B, Kambouchner M, Tazi A, et al. Absence of DNA from mycobacteria of the M. tuberculosis complex in sarcoidosis. Am J Respir Crit Care Med 1997;156:1000-3. (29.) Klemen H, Husain AN, Cagle PT, Garrity ER, Popper HH. Mycobacterial DNA in recurrent sarcoidosis in the transplanted lung--a PCR-based study on four cases. Virchows Arch 2000;436:365-9. (30.) Chao SC, Yan JJ, Lee JY. Cutaneous sarcoidosis among Taiwanese. J Formosan Med Assoc 2000;99:317-23. (31.) Se Thoe SY, Tay L, Sng EH. Evaluation of amplicon- and IS6110-PCR for direct detection of Mycobacterium tuberculosis complex in Singapore. Trop Med Int Health 1997;2:1095-101. (32.) van Soolingen D, de Haas PE, Hermans PW, Groenen PM, van Embden JD. Comparison of various repetitive DNA elements as genetic markers for strain differentiation and epidemiology of Mycobacterium tuberculosis. J Clin Microbiol 1993;31:1987-95. (33.) Bifani P J, Shopsin B, Alcabes P, Mathema B, Kreiswirth BN, Liu Z, et al. Molecular epidemiology and tuberculosis control. JAMA JAMA abbr. Journal of the American Medical Association 2000;284:305-7. (34.) Pace NR. A molecular view of microbial diversity and the biosphere. Science 1997;276:734-40. Wonder Puryear Drake, * Zhiheng Pei, ([dagger]) David T. Pride, ([dagger]) Robert D. Collins, * Timothy L. Cover, * and Martin J. Blaser Martin J. Blaser, MD is the Frederick H. King Professor of Internal Medicine, Chairman, Department of Medicine, and Professor of Microbiology at New York University School of Medicine. He is an established researcher in microbiology and infectious diseases. ([dagger]) * Vanderbilt University School of Medicine and Veterans Affairs Medical Center, Nashville, Tennessee, USA; and ([dagger]) New York University New York University, mainly in New York City; coeducational; chartered 1831, opened 1832 as the Univ. of the City of New York, renamed 1896. It comprises 13 schools and colleges, maintaining 4 main centers (including the Medical Center) in the city, as well as the School of Medicine and Veterans Affairs Medical Center, New York, New York, USA Dr. Drake is supported in part by the Robert Wood Johnson Robert Wood Johnson was the name shared by members of the family that descended from the President of Johnson & Johnson:
Dr. Drake is assistant professor of medicine at Vanderbilt University School of Medicine in the Department of Infectious Diseases. Her interests include the investigation of possible infectious etiologic agents for chronic inflammatory states, such as sarcoidosis, by using molecular assays. Address for correspondence: Wonder Drake, Division of Infectious Diseases, Vanderbilt University Medical Center The Vanderbilt University Medical Center (VUMC) is a collection of several hospitals and clinics associated with Vanderbilt University in Nashville, Tennessee. It comprises the following units:[2]
MCN Maternal Child Nursing MCN American Journal of Maternal/Child Nursing MCN Motorcycle Consumer News MCN Migrant Clinicians Network MCN Molecular and Cellular Neuroscience , Nashville, TN 37232, USA; fax: 615-343-6160; e-mail: wonder.drake@mcmail.vanderbilt.edu |
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