Abstract
Although homeless segment of the society could be the hotspots for tuberculosis (TB) transmission, there is little data on TB in homeless individuals in Ethiopia. The objective of this study was to investigate the molecular epidemiology and drug sensitivity of Mycobacterium tuberculosis (M. tuberculosis) isolated from homeless individuals in Addis Ababa, Ethiopia. The study was conducted on 59 M. tuberculosis isolates, which were recovered by the clinical screening of 5600 homeless individuals and bacteriological examination of 641 individuals with symptoms of pulmonary tuberculosis (PTB). Region of difference-9 (RD9) based polymerase-chain reaction (PCR), Spoligotyping and 24-loci Mycobacterial Interspersed Repetitive Unit-Variable Number Tandem Repeat (MIRU-VNTR) typing were used for genotyping of the isolates. In addition, drug sensitivity test was performed on the isolates using BD Bactec Mycobacterial Growth Inhibition Tube (MGIT) 960. Fifty-eight of the 59 isolates were positive by spoligotyping and spoligotyping International type (SIT) 53, SIT 37, and SIT 149 were the dominant spoligotypes; each consisting of 19%, 15.5%, and10.3% of the isolates, respectively. The majority of the isolates (89.7%) were members of the Euro-American (EA) major lineage. MIRU-VNTR identified Ethiopia_3, Delhi/CAS, Ethiopia_2, TUR, X-type, Ethiopia_H37Rv-like strain, Haarlem and Latin-American Mediterranean (LAM) sub lineages. The proportion of clustering was 77.6% (45/58) in spoligotyping while it was 39.7% (23/58) in 24-loci MIRU-VNTR typing. Furthermore, the proportion of clustering was significantly lowered to 10.3% (6/58) when a combination of spoligotyping and 24-loci MIRU-VNTRplus was used. The recent transmission index (RTI) recorded by spoligotyping, 24-loci MIRU-VNTR typing, and a combination of the two genotyping methods were 58.6%, 27.6% and 5.2%, respectively. Young age and living in groups were significantly associated with strain clustering (P < 0.05). The drug sensitivity test (DST) result showed 8.9% (4/58) of the isolates were resistant to one or more first line ant-TB drugs; but multidrug resistant isolate was not detected. Clustering and RTI could suggest the transmission of TB in the homeless individuals, which could suggest a similar pattern of transmission between homeless individuals and the general population. Hence, the TB control program should consider homeless individuals during the implementation of TB control program.
Similar content being viewed by others
Introduction
Tuberculosis (TB), caused by members of the Mycobacterium tuberculosis complex (MTBC), is one of the leading causes of death from single infectious agent globally, accounting for about 1.5 million deaths and 10 million new cases each year1,2. An estimated 10.6 million people fell ill with TB in 2021, an increase of 4.5% from 2020 and 1.6 million people died from the disease3. The burden of drug-resistant TB also increased by 3% between 2020 and 2021, with 450,000 new cases of rifampicin-resistant TB (RR-TB) in 2021. The COVID-19 pandemic continues to have a damaging impact on access to TB diagnosis and treatment thereby leading to rise in the burden of TB disease. The progress made in the years up to 2019 has slowed, stalled or reversed and global TB targets are off track3.
Ethiopia is one of the 30 countries with a high burden of TB, MDR-TB and TB-HIV co-infection in the world3. In 2021, there were an estimated 119 incident TB cases per 100,000 populations in Ethiopia3. The current prevalence of MDR-TB in Ethiopia is 1.1% and 12% in new and previously treated TB cases, respectively3. On the other hand, a cross sectional study conducted on 228 individuals with chronic psychotic disorders at St. Amanuel Mental Specialized Hospital in Addis Ababa reported 9.8% drug resistant TB4.
Although homelessness is a worldwide crisis, the problem is more serious in developing countries like Ethiopia5. In Ethiopia, particularly in the major cities, homelessness is becoming a serious social problem5,6. The streets of Addis Ababa, the capital of Ethiopia, are said to be homes to a population of between 60,000 to100, 000 individuals7,8. Most of young homeless individuals residing in Addis Ababa city are migrants from rural areas in search of better opportunities although some have originated from the City itself5. Migration is predominantly caused by lack of support from social networks, lack of access to employment and income-generating opportunities, internal conflict, lack of access to affordable housing and lack of access to an effective social protection system7,8.
Homeless individuals live in conditions that are not conducive for living. They are exposed to risk factors of TB such as addiction to smoking, alcohol and drug5,7. In addition, the absence of shelter, HIV infection, overcrowding, lack of ventilation system and malnutrition increase the susceptibility of homeless individuals to TB infection. Understanding of local TB transmission would benefit both the infection control and management, which would ultimately result in a better patient care. Molecular epidemiological studies are very useful in identifying the TB bacilli strains that are circulating in specific geographic region or in specific group of human population such as the homeless individuals9. Furthermore, molecular epidemiological studies help in identifying the presence of ongoing active TB transmission as well as in differentiating reactivated infection from new infection. While investigation of drug sensitivity profiles of isolates would contribute to effective treatment of cases and alerts the TB control programs in containing MDR and extensive drug resistant isolates.
Studies from other countries show that strains of M. tuberculosis that infect homeless individuals are similar with those which infect the general community9. For instance, Haarlem, LAM and T sub-lineages were more frequently isolated from homeless individuals and general population in Colombia9. However, in Ethiopia although several molecular epidemiological studies conducted in the general population in different areas, no such study was conducted in marginalized homeless individuals. This study was initiated with the objective of investigating the molecular epidemiology of TB in homeless individuals who reside in the Addis Ababa city by using a combination of spoligotyping and 24-loci MIRU-VNTR genotyping methods10. The majority of the homeless individuals in Addis Ababa city were migrated to the City from different regional states of Ethiopia. Hence, they could be infected with different strains of M. tuberculosis which are circulating in different parts of the country. Therefore, the genetic diversity of the strains of M. tuberculosis that would be isolated from the homeless individuals in Addis Ababa could partly represent the diversity of M. tuberculosis strains at the national level. Moreover, evaluation of the drug sensitivity profiles of the M. tuberculosis isolated from the homeless individuals in Addis Ababa would generate valuable information on the magnitude of drug resistance, which would help the TB control program in planning effective control methods. Therefore, the objectives of this study were to investigate the molecular epidemiology and evaluate the drug sensitivity of M. tuberculosis isolated from homeless individuals in Addis Ababa city, Ethiopia.
Materials and methods
Study setting and design
A cross-sectional study was conducted among homeless individuals diagnosed with PTB between February 2019 and December 2020 in Addis Ababa, Ethiopia. All methods were performed in accordance with the relevant guidelines and regulations. During the study period Addis Ababa city Administration has established temporary shelters for homeless individuals. The shelters provided meal, bedding, clothing, health care service and counseling. Voluntary homeless individuals were enrolled from the streets of Addis Ababa city by the outreach program to get the shelter services. Eligible and voluntary homeless individuals were screened for the symptoms of PTB upon admission to the shelters. A total of 5600 homeless individuals were screened for the symptoms of PTB using WHO TB symptoms screening guidelines11. Xpert MTB/RIF assay and M. tuberculosis culture were performed on 641 sputum samples to isolate M. tuberculosis. M.tuberculosis isolates recovered from culture were examined with region of difference-9 (RD9)-based polymerase chain reaction (PCR), spoligotyping and 24-loci MIRU-VNTR typing. DST was performed using BD Bactec Mycobacterial Growth Inhibition Tube (MGIT) 960.
Lowenstein-Johnson culture of sputum
Sputum samples were digested and decontaminated by the modified Petroff method12. Briefly, samples were decontaminated with equal volume of 4% NaOH for 15 min; the remaining volume was filled with 9 ml sterile phosphate buffer saline (PBS) and centrifuged at speed of 3000g for 15 min. A drop of phenol red was added to a pellet as pH indicator and neutralized using 10% HCl. Of the neutralized pellet, 0.25–0.5ml specimen was inoculated onto two slopes of Lowenstein-Johnson (LJ) media. One of the LJ media supplemented with 0.6% glycerol and the other with 0.75% pyruvate. Inoculated media were incubated at 37 °C for up to 8 weeks with weekly follow up. Culture was considered negative after 8 weeks if colony was not observed.
DNA extraction
Extraction of mycobacterial DNA was performed by boiling a loop full of fresh grown bacterial colonies in 100 µL dH2O at 80 °C for 60 min. The extracted DNA samples were stored at – 80 °C until when spoligotyping and MIRU-VNTR typing were performed.
Typing of Mycobacterium tuberculosis complex isolates
Three different molecular typing methods were used. First, region of difference 9 (RD9) based PCR was used for the differentiation of M. tuberculosis from the other members of MTBC. Secondly, the M. tuberculosis isolates were genotyped using spoligotyping for strain identification although it has low discriminatory power. Lastly 24-loci MIRU-VNTR was used for identification of the strains of M. tuberculosis. Thus, both spoligotyping and 24-loci MIRU-VNTR were used for identification of the strains of M. tuberculosis. A combination of spoligotyping and 24-loci MIRU-VNTR was used in order to get a higher resolution power than using either spoligotyping or MIRU-VNTR alone.
Region of difference-9 based polymerase chain reaction
Region of difference (RD) 9-based PCR was performed on heat-killed cells to confirm the presence or absence of RD9 for species identification of M. tuberculosis from the other members of MTBC as previously described13. The PCR reaction was used three primers (RD9 flankF, RD9intR and RD9 flankR). Amplification of the mixtures was performed using a Thermal Cycler PCR machine. The PCR amplification product was run by electrophoresis in 1.5% agarose gel in 1 × Tris Borate-EDTA (TBE) running buffer at 110 V and 400 mA for 35 min. Ethidium bromide at a ratio of 1:10, 100 base pair (bp) DNA ladder and orange 6 × loading dye were used in gel electrophoresis and the gel was visualized. The results were interpreted as M. tuberculosis when a band size of 396 bp was observed (RD-9 positive), while detection of a band size of 575 bp was considered as positive for the other MTBC species. DNA from M. bovis BCG and M. tuberculosis H37Rv were used as positive controls, whereas distilled water was used as a negative control13.
Spoligotyping
Spoligotyping was performed for MTBC isolates as described by Kamerbeek et al.14. The results of spoligotyping were interpreted in binary format and lineages were assigned using an updated version of the SIVITWEB (http://www.pasteur-guadeloupe.fr:8081/SITVIT2/) and the major lineages were analyzed using an online tool Run TB-Lineage http://tb.insight.cs.rpi.edu/run_tb_lineage.html. We also used a conformal Bayesian network (CBN) and knowledge based Bayesian network (KBBN) analyses to predict the major lineages and sub-lineages. Isolates which have similar pattern with those in the SITVIT database were assigned a SIT number while, new isolates were considered as “Orphan” strains14.
Mycobacterial interspersed repetitive unit-variable number tandem repeat typing
The MTBC DNA samples were subjected to MIRU-VNTR typing as previously described10. Laboratory results of MIRU-VNTR typing were interpreted using the MIRU-VNTRplus database (http://www.miru-vntrplus.org) to determine MTBC lineages and relatedness. A minimum spamming tree (MST) was constructed. Previously identified Ethiopian strains were assigned manually to Ethiopia_2 and Ethiopia_3 based on the absence of spacer 13 and 10–19, respectively15,16,17. All the molecular typing tests were performed at the Aklilu Lemma Institute of Pathobiology (ALIPB), Addis Ababa University (AAU), Addis Ababa, Ethiopia.
Drug susceptibility testing
Drug susceptibility test (DST) was performed at National Tuberculosis Reference Laboratory, Ethiopian Public Health Institute (EPHI), Addis Ababa; using liquid Mycobacterium Growth Indicator Tube system (MGIT) 960 as previously described17. The critical concentrations of the anti-TB drugs used for this study were: streptomycin (STM) 1µg, Isoniazid (INH) 0.1µg, Rifampicin (RIF) 1µg and Ethambutol (EMB) 5µg18.
Statistical analysis
The data were analyzed using SPSS version 26 statistical software. The discriminatory power of genotyping methods were determined by the Hunter-Gaston Discrimination Index (HGDI)19.
where N is the total number of isolates, s is the total number of different patterns and nj is the number of isolates belonging to the jth pattern. The allelic diversity (h) of each of the 24-loci MIRU-VNTR was determined from the MIRU-VNTRplus. Lineage identification of MTBC isolates was carried out by best match analysis and tree-based identification tools on the MIRU-VNTRplus database (http://www.miru-vntrplus.org)20. The classification of the isolates by MIRU-VNTR and spoligotyping was performed based on dendrogram provided in the MIRU-VNTRplus by the construction of a NJ based phylogenetic tree20. The genotype clustering rate was estimated by n-1 method21 according to the formula described earlier22 (nc-c)/n; where n is the total number of cases in the sample, c is the number of clusters and nc is the total number of clustered cases in the cluster. The association between clustered strains and predictive variables were computed using logistic regression analysis. P-value < 0.05 was considered statistically significant.
Ethical consideration
The protocol of the study was approved by the Addis Ababa University, College of Natural and Computational Sciences Institutional Review Board (IRB) (Ref. No. IRB/036/2018). Additionally, Ethical clearance was obtained from the Addis Ababa City Administration Health Bureau (Ref. No. A/A/H/3981/227). Then, a support letter was obtained from Addis Ababa City Administration, Labor and Social Affairs Bureau (Ref. No. A/A/L/S/66/116/163). Written informed consent was obtained from all the study participants who provided sputum samples after providing adequate information on the possible benefits and risks of the study. Patients found AFB or Xpert positive were referred to the clinics in the temporary shelters for treatment under the directly observable therapy short course (DOTS) program.
Results
Socio-demographic and clinical characteristics of the study participants
Out of total 5600 homeless individuals screened for PTB symptoms, 80.3% (4500/5600) were males. The median and mean ± SD age of study participants was 23 and 27.8 ± 9.5 years, respectively. Seventy percent (4869/5600) and 47.0% (2631/5600) of the study participants were not married and completed at least primary education, respectively. Over 90% (5060/5600) of the homeless individuals migrated to Addis Ababa City from the regional states of Ethiopia. Of the 5600 participants screened for PTB symptoms, 641 presumptive TB cases were identified on the basis of clinical signs and then further subjected to bacteriological examination (Table 1). Totally, 59 bacteriologically confirmed TB cases identified by the GeneXpert and LJ culture. Then, the 59 isolates were identified using RD 9-based PCR, spoligotyping and MIRU-VNTR typing.
Speciation of the isolates using RD 9-based PCR
Based on the RD9-based PCR, out of 59 bacteriologically confirmed isolates, 58 isolates were confirmed to be M. tuberculosis. One isolate did not give valid result, which could be due to insufficient DNA content or laboratory contamination. The isolates were further genotyped using spoligotyping and 24-loci MIRU-VNTR typing for the identification of lineages and strains.
Spoligotyping based identification of lineages and sub-lineages
The results of spoligotyping are presented in Tables 2 and 3 while the raw data of the spoligotyping are presented in Supplementary 1. On the basis of spoligotyping, 81% (47/58) of the isolates belonged to 16 shared international types i.e. SIT numbers could be assigned to 81% of the isolates while SIT numbers could not be assigned to 19% (11/58) of the total isolates. As a result, these isolates were classified as orphans (Table 3). In terms of frequency, SIT53, SIT149 and SIT37 were the three most frequently identified spoligotypes, and consisting of 11, 9 and 6 isolates, respectively. Furthermore, TB-insight RUN TB-lineage analysis revealed that Euro-American (L4) (EA) was the most prevalent lineage consisting of 89.7% (52/58) of the total isolates. The second most prevalent lineage was East-African Indian (L3) consisting of 8.62% (5/58) isolates while Indo-Oceanic (L1) lineage was the least prevalent lineage as only one isolate belonged to it.
Mycobacterial interspersed repetitive unit-variable number tandem repeat typing based identification of sub-lineages and allelic diversity
The raw data of MIRU-VNTR are presented in Supplementary 1 while representative images of MIRU-VNTR gel are presented in Supplementary 2A–D. The 24-loci MIRU-VNTR typing identified Ethiopia_3 (34.5%), Delhi/CAS (12.1%), Ethiopia_2 (10.3%), TUR (10.3%), X-type (8.6%), Ethiopia_H37Rv-like strain (6.9%), Haarlem (6.9%) and LAM (1.7%) sub-lineages. However, 8.6% of the isolates could not be assigned to lineages using MIRU-VNTRplus database. Based on the logistic regression analysis, young age (AOR = 4.8, 95% CI 1.56, 8.24) and living in a group were significantly (AOR = 7.2, 95% CI 4.64, 15.41) associated with the clustering of M. tuberculosis strains (Table 4).
Allelic diversity (h) for each MIRU-VNTR locus is presented in Table 5. MIRU-VNTR loci are classified based on their allelic diversity and ability to differentiate between the isolates. Eleven MIRU-VNTR loci (424, 802, 960, 1644, 1955, 2163b, 2347, 2401, 2996, 4052 and 4156) were highly discriminative (HGI > 0.6) while 10 MIRUVNTR loci (577, 580, 2059, 2165, 2461, 2531, 3007, 3192, 3690 and 4348) were moderately discriminative (0.3 < HGI < 0.6). The remaining three MIRU-VNTR loci (154, 2687 and 3171) were poorly discriminative (HGI < 0.3) (Table 5).
Minimum spanning tree analysis
Utilizing MIRU-VNTR data, Minimum spanning tree (MST) was constructed in which genotypes of isolates were linked based on double-locus variants (Fig. 1). Twenty-two genotypes (corresponding to 24 isolates) were grouped into 7 clonal complexes, leaving 34 singletons patterns. Clonal complexes 1 and 2 contained nine and three genotypes, respectively while clonal complexes 3, 4, 5, 6 and 7 each contained two genotypes, respectively. The MIRU-VNTR dendrogram constructed using http://WWW.miruvntrplus.org/MIRU/index is presented in Fig. 2. The dendrogram grouped the 58 isolates into 7 clonal groups. The 2nd group had a single isolate. The 1st, 3rd, 4th, 5th, 6th and 7th groups had 3, 9, 21, 10, 4 and 10 isolates, respectively.
Discriminatory power of spoligotyping and 24-loci mycobacterial interspersed repetitive unit-variable number tandem repeat typing
The discriminatory power of spoligotyping and 24-loci MIRU-VNTR were 0.9864 and 0.9987, respectively. The analysis of spoligotyping resulted in 24 different spoligotype patterns of which 11 were clustered and 13 were unique. MIRU-VNTRplus analysis resulted in 55 different patterns of which 3 were clustered and 52 unique. The overall clustering rate based on a combination of spoligotyping and 24-loci MIRU-VNTR was 10.3% while the RTI was 5.2% based on a combination both genotyping methods (Table 6).
Drug susceptibility test
The drug susceptibility testing (DST) data was available for 76.3% (45/59) isolates. The result showed that 91.1% (41/45) of the strains were pan-susceptible while the remaining 8.9% (4/45) was mono-resistant to the first-line anti-TB drugs. Mono-resistance to either INH or SM was 4.4%. No isolate was MDR. All isolates that were resistant to first-line anti-TB drugs were tested for the second-line drugs and none were found resistant. Ethiopia_3 strains were exhibited higher percentage (6.7%) of resistance to at least one of the first-line anti-TB drugs as compared to the other strains.
Discussion
This study was the first of its kind to investigate the molecular epidemiology and drug sensitivity of M. tuberculosis in the homeless individuals in Addis Ababa, Ethiopia. The study identified moderately diverse strains of M. tuberculosis in the homeless individuals. The clustering rate was also moderate in the homeless individuals. Clustering of strains was associated with young age and living in a group in one place. The isolates showed a moderate magnitude of drug resistance to first-line anti-TB drugs while no MDR-TB isolate was detected.
Based on the results of the spoligotyping, the Euro-American lineage (L4) (EA) was the most prevalent (89.7%) lineage identified in this study. This observation was consistent with the findings of previous studies, which showed the high prevalence of L4 in the world at large23 and also in Ethiopia24,25,26,27,28,29,30. Furthermore, two reviews on the genetic diversity of M. tuberculosis strains in Ethiopia indicated that the prevalence of L4 is higher than the prevalence of the other lineages31,32. Following to L4, the second most prevalently isolated lineage was L3. This observation is also consistent with the findings other studies reported from Ethiopia24,25,26,27,28,29,30. The reason for the high prevalence of L3 and L4 could be due to the fact that these lineages belong to the modern M. tuberculosis lineages which are characterized by high potential of transmissibility as compared to ancient M. tuberculosis lineages33. On top of L3 and L4, the Indo-oceanic lineage (L1) was isolated from the homeless individuals in Addis Ababa. Similarly, L1 was reported from Ethiopia earlier by other researchers24. However, the prevalence of L1 was very low in this study as compared to those of L3 and L4 although other researchers reported that L1 occurs abundantly in East Africa 24.
On the basis of MIRU-VNTR typing, T sub-lineages was the prevalent sub-lineage isolated by this study. This observation is consistent with results of previous studies in Ethiopia16,34. Earlier study documented that the T sub-lineages are specific to Ethiopia. And the result of this study thus re-affirmed the finding of the earlier study15. The T sub-lineages belong to L7 which has been isolated only from Ethiopia but not yet from other countries15. L7 is not widely spread even in Ethiopia and most commonly isolated from northeastern Ethiopia. Hence, because of its limited geographic scope in Ethiopia, the chance of its spread to other countries could be minimal. However, the present geographic scope of this lineage could change in the future thereby favoring its widespread in Ethiopia and neighboring countries. Ethiopia_3 was the predominant Ethiopia specific sub-lineage followed by the Ethiopia-2, similar to previous studies conducted in northwestern16 and eastern Ethiopia35. In contrast, studies conducted in southern Ethiopia29 reported that sub-lineages Ethiopia_2 the dominant sub-lineage in southern Ethiopia. Ethiopia_H37Rv-like genotype which shares a common ancestor with H37Rv laboratory reference strains was also isolated by the present study and earlier similar studies36,37,38,39.
Furthermore, Delhi/CAS was the second most prevalent sub-lineage detected in the homeless individuals in Addis Ababa. This result agrees with the results of several previous studies in Ethiopia17,26,29,33,34,40. Likewise, the Delhi/CAS sub-lineage was also prevalent in Tanzania41, Sudan42, Uganda43 and Kenya44. Although this lineage is presumed to be geographically specific to India and central Asia, the bi-directional socioeconomic relationship between Ethiopia and India might have increased the spread of Delhi/CAS lineage from India to Ethiopia. In this regard, Ethiopia was the first African country to open an embassy in New Delhi in 1948, which strengthened the relationship between the two countries as well as people to people interaction thereby favoring the transmission of the Delhi/CAS sub-lineage between Indians and Ethiopians. On top of this, isolation of the Delhi/CAS sub-lineage from homeless individuals in Addis Ababa could be substantiated by the theory of “Out of Africa”45 which stated that the origin of human beings and M. tuberculosis is East Africa. This theory thus indirectly suggested that Delhi/CAS and the other sub-lineages of M. tuberculosis could be found in East African countries like Ethiopia.
The proportion of Manu sub-lineage recorded by the present study was similar with those reported by previous studies conducted in Ethiopia46 and Egypt47. Although the Manu sub-lineage is less commonly reported from Ethiopia, its isolation could be associated with large number of Chinese in Ethiopia during the last three decades and their interaction with local people in different jobs such as construction and industrial enterprises. Similar to the result of the present study, the Turkey lineage was also isolated earlier in Ethiopia26,29 which could be due to the introduction of this lineage to Ethiopia from Turkey or Saudi Arabia to Ethiopia by movement of infected individuals in relation to growing economic partnership between Ethiopia and Turkish and/or Saudi Arabia. Furthermore, it could also be introduced to Ethiopia by the return of infected Ethiopian immigrants from Saudi Arabia/Turkey to Ethiopia48. Besides, the isolation of the Turkey sub-lineage in homeless individuals in Addis Ababa could be supported by the theory that stated East Africa is the origin MTBC members45.
The Haarlem sub-lineage is one of the common sub-lineages isolated in this study and it is believed to descend from the European and Middle East countries44,49,50,51. And its isolation from the Ethiopians is not surprising because of the long history of interactions between Ethiopians, and Europeans or people from the Middle East countries. Furthermore, the LAM sub-lineage is commonly isolated from Ethiopia as observed in this study34,40. Similarly, the LAM sub-lineage has been reported form the other east African countries such as Tanzania44, Uganda52 and Kenya41. Furthermore, similar to the results of the present study, the Haarlem, LAM and T sub-lineages were isolated from homeless individuals in Colombia9.
In the present study, majority of the MIRU-VNTR alleles were highly and moderately discriminant as evaluated by the allelic diversity (h) result, which in turn indicates the representativeness of the study population10. Furthermore, the finding of highly and moderately discriminant alleles suggest that the loci were suitable for genotyping of the isolates.
The results of MST and dendrogram analyses strains of M. tuberculosis isolated from homeless were consistent with the results of similar previous studies conducted in Ethiopia17,53.
Based on the generated data from spoligotyping and MIRU-VNTR, it is possible to say that these two genotyping methods can complement each other. But they have different precisions. For instance, SITVITWEB can only identify three Haarlem and five Delhi/CAS while MIRU-VNTRplus can identify four Haarlem and nine Delhi/CAS. These discrepancies probably associated with the algorithm used by such database. Nevertheless, the profiles of 19% (11/58) and 8.6% (5/58) of isolates could not match with the profiles strains that are found in SIVITWEB and MIRU-VNTRplus databases, respectively.
The proportion of clustering in this study by using spoligotyping and 24-loci MIRU-VNTR typing was in agreement with previous similar studies conducted in Ethiopia16,48,54,55,56. However, the clustering rate based on a combination of spoligotyping and 24-loci MIRU-VNTR typing was lower than other previous studies in Ethiopia17,30 and higher than a study reported from South Omo Zone Ethiopia29. The differences in clustering rate among studies could be due to variations in geography, population density, ethnicity and socio-economic diversity57. The significant clustering rate in our study could also be associated with presence of TB transmission among homeless individuals in Addis Ababa City which may due to overcrowding and other associated risk factors that favor the transmission of TB. Other previous studies have reported socio-demographic factors to be predictors of recent TB transmission, such as young age, ethnicity status, male sex, homelessness, incarceration, and overcrowding and drug abuse57. In our study, young age and overcrowding were significantly associated with clustering, indicating that homeless individuals are at risk of developing TB9, and also linked to recent transmission of TB in this population. Strains of the Ethiopia_3 sub-lineage were more likely to be clustered which could suggest a more frequent transmission of this strain in the homeless individuals.
Although the number of the isolates was small, 8.9% isolates was resistant to one or more first-line ant-TB drugs. Other studies in Ethiopia and in the other countries reported similar percentages of drug resistance4,58,59,60. Fortunately, MDR isolate was not detected in the isolates of this study. Similarly, other studies conducted earlier reported the absence of MDR isolates57,58. Nonetheless, the risk factor for the development of MDR in the homeless individuals is expected to be more likely.
Limitations of the study
Only LJ was used for culturing M. tuberculosis and the small number of isolates were used for this study which could limit the precision of estimate of the relationship between homelessness and TB. Moreover, the lower sensitivity of phenotypic DST methods and lack of molecular confirmation for drug resistance strains of M. tuberculosis could also limit the precision of the results. However, regardless of its limitations, the result of the study could be considered as a valued input for the TB control program of the country.
Conclusion
In the present study, the clustering rate of M. tuberculosis isolates was 10.3% based on a combination of spoligotyping and 24-loci MIRU-VNTR genotyping methods. Young age and living in groups were significantly associated with strain clustering. These observations could suggest that the majority of TB cases in the homeless individuals in Addis Ababa city are attributable to recent transmission. This could also suggest the potential role of homeless individuals in the transmission of TB to the general population. Besides, fortunately no MDR isolate was detected while a moderate magnitude of drug resistance to first-line anti-TB drugs was recorded. Based on this conclusive remarks, the Addis Ababa city TB control program is advised to consider homeless individuals in its TB control program.
Data availability
The datasets generated and/or analysed during this study are included in this published article in Supplementary 1 files.
References
WHO. Global Tuberculosis Report 2019 (World Health Organization, 2019).
Micheni, L. N., Kassaza, K., Kinyi, H., Ntulume, I. & Bazira, J. Detection of Mycobacterium tuberculosis multiple strains in sputum samples from patients with pulmonary tuberculosis in south western Uganda using MIRU-VNTR. Sci. Rep. 12, 1656–1666 (2022).
WHO. Global Tuberculosis Report 2021 (World Health Organization, 2021).
Temesgen, E., Belete, Y., Haile, K. & Ali, S. Prevalence of active tuberculosis and associated factors among people with chronic psychotic disorders at St. Amanuel Mental Specialized Hospital and Gergesenon Mental Rehabilitation center, Addis Ababa, Ethiopia. BMC Infect. Dis. 21, 1–9 (2021).
Shamebo, T. et al. Prevalence of pulmonary tuberculosis in homeless individuals in the Addis Ababa city, Ethiopia. Front. Public Health 11, 1128525 (2023).
Fekadu, A. et al. Burden of mental disorders and unmet needs among street homeless people in Addis Ababa, Ethiopia. BMC Med. 12, 1–2 (2014).
Habtamu, D. & Adamu, A. Assessment of sexual and reproductive health status of street children in Addis Ababa. J. Sex Transm. Dis. 2013, 524076 (2013).
Bennett, C. United Nations Office for the Coordination of Humanitarian Affairs (UNOCHA) Orientation Handbook (United Nations Office for the Coordination of Humanitarian Affairs (UNOCHA), 2002).
Hernández Sarmiento, J. M. et al. Tuberculosis among homeless population from Medellín, Colombia: Associated mental disorders and socio-demographic characteristics. J. Immigr. Minor. Health 15, 693–699 (2013).
Sola, C. et al. Genotyping of the Mycobacterium tuberculosis complex using MIRUs: Association with VNTR and spoligotyping for molecular epidemiology and evolutionary genetics. Infect. Genet. Evol. 3, 125–133 (2003).
WHO. Systematic Screening for Active Tuberculosis: Principles and Recommendations Vol. 2013 (World Health Organization, 2013).
Kent, P. T. Public Health Mycobacteriology: A Guide for the Level III Laboratory (Public Health Service, Centers for Disease Control, 1985).
Grange, J. M. & Zumla, A. I. Human tuberculosis due to Mycobacterium bovis and related animal pathogens. In Tuberculosis (eds Grange, J. M. & Zumla, A. I.) 146–153 (WB Saunders, 2009).
Kamerbeek, J. et al. Simultaneous detection and strain differentiation of Mycobacterium tuberculosis for diagnosis and epidemiology. J. Clin. Microbiol. 35, 907–914 (1997).
Firdessa, R. et al. Mycobacterial lineages causing pulmonary and Extrapulomnary tuberculosis, Ethiopia. Emerg. Infect. Dis. 19, 460–463 (2013).
Biadglegne, F., Merker, M., Sack, U., Rodloff, A. C. & Niemann, S. Tuberculous lymphadenitis in Ethiopia predominantly caused by strains belonging to the Delhi/CAS lineage and newly identified Ethiopian clades of the Mycobacterium tuberculosis complex. PLoS One 10, e0137865 (2015).
Tessema, B. et al. Molecular epidemiology and transmission dynamics of Mycobacterium tuberculosis in Northwest Ethiopia: New phylogenetic lineages found in Northwest Ethiopia. BMC Infect. Dis. 13, 1–11 (2013).
Gumi, B. Zoonotic transmission of tuberculosis between pastoralists and their livestock in South-East Ethiopia. EcoHealth 9, 139–149 (2012).
Hunter, P. R. & Gaston, M. A. Numerical index of the discriminatory ability of typing systems: An application of Simpson’s index of diversity. J. Clin. Mircobiol. 26, 2465–2466 (1988).
Allix-Béguec, C., Harmsen, D., Weniger, T., Supply, P. & Niemann, S. Evaluation and strategy for use of MIRU-VNTR plus, a multifunctional database for online analysis of genotyping data and phylogenetic identification of Mycobacterium tuberculosis complex isolates. J. Clin. Mircobiol. 46, 2692–2699 (2008).
Glynn, J. R., Vyonycky, E. & Fine, P. E. M. Influence of sampling on estimates of clustering and recent transmission of Mycobacterium tuberculosis derived from DNA fingerprinting techniques. Am. J. Epidemiol. 149, 366–371 (1999).
Meehan, C. J. The relationship between transmission time and clustering methods in Mycobacterium tuberculosis epidemiology. EBioMedicine 37, 410–416 (2018).
Reed, M. B. et al. Major Mycobacterium tuberculosis lineages associate with patient country of origin. J. Clin. Mircobiol. 47, 1119–1128 (2009).
Korma, W. et al. Clinical, molecular and drug sensitivity pattern of mycobacterial isolates from extra-pulmonary tuberculosis cases in Addis Ababa, Ethiopia. BMC Infect. Dis. 15, 1–12 (2015).
Diriba, G. Mycobacterial lineages associated with drug resistance in patients with extrapulomnary tuberculosis in Addis Ababa, Ethiopia. Tuberc. Res. Treat. 2021, 1–7 (2021).
Bedewi, Z. et al. Molecular typing of Mycobacterium tuberculosis complex isolated from pulmonary tuberculosis patients in central Ethiopia. BMC Infect. Dis. 17, 1–8 (2017).
Debebe, T., Admassu, A., Mamo, G. & Ameni, G. Molecular characterization of Mycobacterium tuberculosis isolated from pulmonary tuberculosis patients in Felege Hiwot Referral Hospital, northwest Ethiopia. J. Mirobiol. Immunol. Infect. 47, 333–338 (2014).
Garedew, L. Strain diversity of mycobacteria isolated from pulmonary tuberculosis patients at Debre Birhan Hospital, Ethiopia. Int. J. Tuberc. Lung Dis. 17, 1076–1081 (2013).
Wondale, B. Molecular epidemiology of clinical Mycobacterium tuberculosis complex isolates in South Omo, Southern Ethiopia. BMC Infect. Dis. 20, 1–12 (2020).
Mekonnen, A. et al. Molecular epidemiology and drug resistance patterns of Mycobacterium tuberculosis complex isolates from university students and the local community in Eastern Ethiopia. PLoS One 13, e0198054 (2018).
Mekonnen, D. et al. Molecular epidemiology of M. tuberculosis in Ethiopia: A systematic review and meta-analysis. Tuberculosis 118, 101858–101899 (2019).
Tulu, B. & Ameni, G. Spoligotyping based genetic diversity of Mycobacterium tuberculosis in Ethiopia: A systematic review. BMC Infect. Dis. 18, 1–10 (2018).
Comas, I. Population genomics of Mycobacterium tuberculosis in Ethiopia contradicts the virgin soil hypothesis for human tuberculosis in Sub-Saharan Africa. Curr. Biol. 25, 3260–3266 (2015).
Agonafir, M. et al. Phenotypic and genotypic analysis of multidrug-resistant tuberculosis in Ethiopia. Int. J. Tuberc. Lung Dis. 14, 1259–1265 (2010).
Ali, S. et al. Drug resistance and population structure of M. tuberculosis isolates from prisons and communities in Ethiopia. BMC Infect. Dis. 16, 1–10 (2016).
Aleksic, E. et al. First molecular epidemiology study of Mycobacterium tuberculosis in Kiribati. PloS One 8, e55423 (2013).
Malm, S. et al. New Mycobacterium tuberculosis complex sublineage, Brazzaville, Congo. Emerg. Infect. Dis. 23, 423–429 (2017).
Niemann, S. et al. Mycobacterium tuberculosis Beijing lineage favors the spread of multidrug-resistant tuberculosis in the Republic of Georgia. J. Clin. Microbiol. 48, 3544–3550 (2010).
Coll, F. et al. A robust SNP barcode for typing Mycobacterium tuberculosis complex strains. Nat. Commun. 5, 4812 (2014).
Mihret, A. et al. Diversity of Mycobacterium tuberculosis isolates from new pulmonary tuberculosis cases in Addis Ababa, Ethiopia. Tuberc. Res. Treat. 2012, 1–7 (2012).
Ogaro, T. D. et al. Diversity of Mycobacterium tuberculosis strains in Nairobi, Kenya. Afr. J. Health Sci. 24, 58–68 (2013).
Sharaf Eldin, G. S. et al. Tuberculosis in Sudan: A study of Mycobacterium tuberculosis strain genotype and susceptibility to anti-tuberculosis drugs. BMC Infect. Dis. 11, 1–8 (2011).
Asiimwe, B. B., Ghebremichael, S., Kallenius, G., Koivula, T. & Joloba, M. L. Mycobacterium tuberculosis spoligotypes and drug susceptibility pattern of isolates from tuberculosis patients in peri-urban Kampala, Uganda. BMC Infect. Dis. 8, 1–8 (2008).
Githui, W. A. et al. Identification of MDR-TB Beijing/W and other Mycobacterium tuberculosis genotypes in Nairobi, Kenya. Int. J. Tuberc. Lung Dis. 8, 352–360 (2004).
Iñaki, C. et al. Out-of-Africa migration and Neolithic co-expansion of Mycobacterium tuberculosis with modern humans. Nat. Genet. 45, 1176–1182 (2013).
Esmael, A., Wubie, M., Desta, K., Ali, I. & Endris, M. Genotyping and drug resistance patterns of M. tuberculosis in Eastern Amhara Region, Ethiopia. J. Clin. Diagn. Res. 2, 2376–0311 (2014).
Helal, Z. H. et al. Unexpectedly high proportion of ancestral Manu genotype Mycobacterium tuberculosis strains cultured from tuberculosis patients in Egypt. J. Clin. Microbiol. 47, 2794–2801 (2009).
Taye, H. et al. Epidemiology of Mycobacterium tuberculosis lineages and strain clustering within urban and peri-urban settings in Ethiopia. PloS One 16, e0253480 (2021).
Demissie, M., Gebeyehu, M. & Berhane, Y. Primary resistance to anti-tuberculosis drugs in Addis Ababa, Ethiopia. Int. J. Tuberc. Lung Dis. 1, 64–67 (1997).
Lari, N. et al. Genetic diversity, determined on the basis of katG463 and gyrA95 polymorphisms, spoligotyping, and IS 6110 typing, of Mycobacterium tuberculosis complex isolates from Italy. J. Clin. Microbiol. 43, 1617–1624 (2005).
Bicmen, C. Molecular characterization of Mycobacterium tuberculosis isolates from Izmir, Turkey. Microbiol. Q. J. Microbiol. Sci. 30, 229–240 (2007).
Kibiki, G. S. et al. M. tuberculosis genotypic diversity and drug susceptibility pattern in HIV-infected and non-HIV-infected patients in northern Tanzania. BMC Microbiol. 7, 1–8 (2007).
Cowan, L. S., Mosher, L., Diem, L., Massey, J. P. & Crawford, J. T. Variable-number tandem repeat typing of Mycobacterium tuberculosis isolates with low copy numbers of IS 6110 by using mycobacterial interspersed repetitive units. J. Clin. Mircobiol. 40, 1592–1602 (2002).
Tadesse, M. et al. The predominance of Ethiopian specific Mycobacterium tuberculosis families and minimal contribution of Mycobacterium bovis in tuberculous lymphadenitis patients in Southwest Ethiopia. Infect. Genet. Evol. 55, 251–259 (2017).
Yimer, S. A. et al. Mycobacterium tuberculosis lineage 7 strains are associated with prolonged patient delay in seeking treatment for pulmonary tuberculosis in Amhara Region, Ethiopia. J. Clin. Microbiol. 53, 1301–1309 (2015).
Tafess, K., Beyen, T. K., Girma, S., Girma, A. & Siu, G. Spatial clustering and genetic diversity of Mycobacterium tuberculosis isolate among pulmonary tuberculosis suspected patients, Arsi Zone, Ethiopia. BMC Pulm. Med. 21, 1–12 (2021).
Sacchi, F. P. C. et al. Genetic clustering of tuberculosis in an indigenous community of Brazil. Am. J. Trop. Med. Hyg. 98, 372 (2018).
Semunigus, T., Tessema, B., Eshetie, S. & Moges, F. Smear positive pulmonary tuberculosis and associated factors among homeless individuals in Dessie and Debre Birhan towns, Northeast Ethiopia. Ann. Clin. Microbiol. Antimicrob. 15, 1–8 (2016).
Haddad, M. B., Wilson, T. W., Ijaz, K., Marks, S. M. & Moore, M. Tuberculosis and homelessness in the United States, 1994–2003. JAMA 293, 2762–2766 (2005).
Story, A., Murad, S., Roberts, W., Verheyen, M. & Hayward, A. C. Tuberculosis in London: The importance of homelessness, problem drug use and prison. Thorax 62, 667–671 (2007).
Acknowledgements
We wish to thank all study participants and data collectors. We are also grateful to the Addis Ababa City Administration Labor and Social Affairs Bureau and Health Bureau for the permission provided to conduct the study. The Department of Microbial, Cellular and Molecular Biology, Addis Ababa University, has provided all rounded support for the research.
Author information
Authors and Affiliations
Contributions
T.S. participated in the conception, design, acquisition of the data, statistical analysis, interpretation of the data, and drafting the manuscript. S.M., A.Z., F.G. and T.M. participated in data acquisition and edition of the manuscript. B.W., B.G. and M.G. participated in the analysis, interpretation of the data, and edition of the manuscript. B.P. and G.A. contributed in the design, guiding the data collection, interpretation of the result, and edition of the manuscript. All authors approved the manuscript for publication and agreed to be accountable for all aspects of the work done.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Shamebo, T., Gumi, B., Zewude, A. et al. Molecular epidemiology and drug sensitivity of Mycobacterium tuberculosis in homeless individuals in the Addis Ababa city, Ethiopia. Sci Rep 13, 21370 (2023). https://doi.org/10.1038/s41598-023-48407-8
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-023-48407-8
- Springer Nature Limited