Mycobacterium tuberculosis review: Difference between revisions

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==Clinical behavior==
==Clinical behavior==
[[Image:Caseating_necrosis.jpg|thumb|330px|left|Figure 5:</b> Granuloma of Tuberculosis. Arrows pointed at multi-nucleated giant cells.<ref>[https://www.creative-biolabs.com/vaccine/mycobacterium-tuberculosis-vaccines.htm]</ref>]]


[[Image:MCaseating necrosis.jpg|thumb|350px|left|<b>Figure 6: </b>Granuloma of Tuberculosis. Arrows pointed at multi-nucleated giant cells.]


===Primary infection===
===Primary infection===
Primary infection, the initial phase, occurs in people without specific immunity, generally normal children and young adults who have not previously been exposed to Mycobacterium tuberculosis.(13). It occur when the inhaled bacteria enter the lung would enter the terminal air space and replicate at alveolar macrophage(12). Some of the infected macrophage would migrate to the close lymph node, and eventually disseminate the infection to remote body parts. Primary infection can be tested by observing the present of granuloma, collection of macrophage ,at the infected area (Figure 4). Primary infection can developed into either latent infection or progressive primary infection. Latent infection take place when the M. tuberculosis have been eliminated by the innate immune system or switch into dormant stage and it is hard to differentiate those two stage based on x ray. Progressive primary infection is observed in 5-10% of patients with primary tuberculosis. Just as its name, the infection gradually worsen and worsen at the 1-2 year of the infection. This infection is developed when the immune system failed to control the out break of virus and it is usually happens at the newborn infant whose immune system is underdeveloped(13).  
Primary infection, the initial phase, occurs in people without specific immunity, generally normal children and young adults who have not previously been exposed to Mycobacterium tuberculosis.<ref name=mary>[https://www.sciencedirect.com/science/article/pii/S0379073810003567?via%3DihubJohan Dempers, M.B.Ch.B., F.C. For. Path. (S.A.), Dip. For. Med. (S.A.), CML (Unisa),a Mary Ann Sens, M.D., Ph.D.,b Shabbir Ahmed Wadee, B.Sc., M.B.Ch.B., M.Med.(For Path.), F.C. For Path.(S.A.),c Hannah C. Kinney, M.D.,d Hein J. Odendaal, M.B.Ch.B., M.Med., F.C O.G.(S.A.), F.R.C.O.G., M.D,e Colleen A. Wright, M.D., M.Med. (Anat. Path.), F.C. Path. (S.A.), F.R.C.Path., F.I.A.C., Ph.D.,f and the PASS NetworkProgressive Primary Pulmonary Tuberculosis Presenting as the Sudden Unexpected Death in Infancy: A Case Report  2010 Aug 11. doi: 10.1016/j.forsciint.2010.07.018]</ref> It occur when the inhaled bacteria enter the lung would enter the terminal air space and replicate at alveolar macrophage.<ref>[https://www.sciencedirect.com/science/article/pii/S0092867401002367?via%3Dihub Michael S. Glickman* and William R. Jacobs, Jr. Microbial Pathogenesis of Mycobacterium tuberculosis: Dawn of a Disciplinehttps://doi.org/10.1016/S0092-8674(01)00236-7 ]</ref> Some of the infected macrophage would migrate to the close lymph node, and eventually disseminate the infection to remote body parts. Primary infection can be tested by observing the present of granuloma, collection of macrophage ,at the infected area (Figure 5). Primary infection can developed into either latent infection or progressive primary infection. Latent infection take place when the M. tuberculosis have been eliminated by the innate immune system or switch into dormant stage and it is hard to differentiate those two stage based on x ray. Progressive primary infection is observed in 5-10% of patients with primary tuberculosis. Just as its name, the infection gradually worsen and worsen at the 1-2 year of the infection. This infection is developed when the immune system failed to control the out break of virus and it is usually happens at the newborn infant whose immune system is underdeveloped<ref name=mary></ref>.


===secondary infection===
===secondary infection===
Secondary infection represent the reactivation of a prior latent or dormant infection and there are 5% to 10% of the secondary infection developed from the latent infection. Secondary infection could occur at any point of the host life, either in several months to decades. There are many factors that governs the occurrence of secondary infection, including the immune state of the host. When the host has experience immunity depression, their likelihood to have a secondary infection is high. Secondary infection is alway with other factors. Patients coinfected with Human immunodeficiency virus (HIV), organ transplant, and IVDU have more than 10-fold risk than the general population. Besides reactivation, secondary infection can also be caused by reinfection through bacteria outside the host.
Secondary infection represent the reactivation of a prior latent or dormant infection and there are 5% to 10% of the secondary infection developed from the latent infection. Secondary infection could occur at any point of the host life, either in several months to decades. There are many factors that governs the occurrence of secondary infection, including the immune state of the host. When the host has experience immunity depression, their likelihood to have a secondary infection is high. Secondary infection is alway with other factors. Patients coinfected with Human immunodeficiency virus (HIV), organ transplant, and IVDU have more than 10-fold risk than the general population. Besides reactivation, secondary infection can also be caused by reinfection through bacteria outside the host.


==Stress tolerance==
==treatment and prevention==
[[Image:bile_salts.png|thumb|300px|right|<b>Figure 10: </b>The <i>shc</i> mutation shows sensitivity in the high concentration of bile salts condition. However, both wild-type strain and <i>shc</i> complemented strain show resistance to bile salts.<ref name=Welander2009/>]]
[[Image:Mycobacterium-tuberculosis-Vaccines-1.jpg|thumb|500px|right|Figure 6:</b> The Infection Mechanism of Mycobacterium tuberculosis<ref>[https://www.creative-biolabs.com/vaccine/mycobacterium-tuberculosis-vaccines.htm]</ref>]]
The abundance and diversity of hopanoid lipids positively influence bacterial resistance to environmental stress, such as the extreme pH, high pressure, non-optical temperature, and high concentration of antibiotic or other lethal chemical compounds.<ref name=Belin2018/> With the help of hopanoid lipids, microbiomes develop different strategies to increase the fitness in non-optical environments. However, most of the detailed mechanisms of stress tolerance induced by the hopanoid lipids remain unclear and require further studies.<ref name=Belin2018/>


===Methylation of hopanoid lipids===
Medical treatment of tuberculosis, together with correct diagnosis, plays an essential  in the management and control of tuberculosis. <ref>[https://www.pnas.org/content/100/24/13881 Rawat R, Whitty A, Tonge PJThe isoniazid-NAD adduct is a slow, tight-binding inhibitor of InhA, the Mycobacterium tuberculosis enoyl reductase: adduct affinity and drug resistance. https://doi.org/10.1073/pnas.2235848100]</ref>Until now, there are no specific single drugs to eliminate mycobacterium tuberculosis. A combination of two stage multiple stage drug therapy is the most common method used on tuberculosis treatment. Adherence to long-term antituberculosis therapy is crucial for maintaining adequate blood drug level and drug resistance can easily evolve from mycobacterium tuberculosis if the patients apply durg inadequately <ref>[https://www.pnas.org/content/100/24/13881 Rawat R, Whitty A, Tonge PJThe isoniazid-NAD adduct is a slow, tight-binding inhibitor of InhA, the Mycobacterium tuberculosis enoyl reductase: adduct affinity and drug resistance. https://doi.org/10.1073/pnas.2235848100]</ref>


Researchers found that under extreme conditions, the biosynthesis of hopanoid lipids increases in most bacterial strains.<ref name=Belin2018/> For example, When <i>[[Rhodopseudomonas palustris]]</i> is placed under extreme environments, such as high temperature or low pH conditions, those stress induces the activation of the <i>ecfG</i> gene, which is a general stress regulator related gene for the alphaproteobacteria. Due to the expression of <i> ecfG </i>, the response factors and regulators upregulate the expression of <i>hpnP</i>, a gene that codes for hopanoid methylases. Therefore, the expression of <i>hpnP</i> increases the rate of hopanoid lipids methylation in bacteria. Methylation increases the hydrophobic characteristics of hopanoid lipids and further decreases the movements of phospholipids hydrophobic tails, perhaps increasing the bacterial membrane resistance to potential dangers.<ref name = Welander2012>[https://onlinelibrary.wiley.com/doi/epdf/10.1111/j.1472-4669.2011.00314.x  Welander P. V., Doughty D. M., Wu C. H., Mehay S., Summons R. E., and Newman D. K.. 2011. Identification and characterization of <i>Rhodopseudomonas palustris</i> TIE-1 hopanoid biosynthesis mutants. Geobiology (2012), 10, 163–177.]</ref>


===Membrane fluidity and permeability===


The presence of hopanoid lipids decreases the fluidity and permeability of bacterial membranes. The hydrophobic part of the hopanoid lipids migrates into the bacterial membrane and moves between the phospholipid tails. Thus, hopanoid lipids fill the empty spaces and increase the membrane integrity. The hydrophilic side chains also form strong attractions with other molecules and environments. Overall, the biomembrane becomes more stable, and the leakage of lethal molecules decrease. Under the low pH or high antibiotic conditions, the protons and antibiotic compounds might experience difficulty across the bacterial membranes due to decreased membrane permeability. Therefore, bacteria show higher resistance towards the high concentration of protons, antibiotics, and other lethal molecules.<ref name=Belin2018/>
In general, there are two different steps in the treatment of tuberculosis can be recognized, the initial (bactericidal) phase and the continuation (sterilizing) phase. The initial phase treatment usually takes place at the first two month of the treatment in which mycobacteria with a high replication rate are killed, and, consequently, with the histological pulmonary restoration and the reduction of the inflammation process, symptoms and clinical signs resolve (clinical recovery) <ref>[https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4790366/ Blanchard JS, Review Molecular mechanisms of drug resistance in Mycobacterium tuberculosis doi: 10.3390/antibiotics3030317]</ref> The initial phase is also known as intensive phase as most of the drugs like , rifampin, Isoniazid, pyrazinamide, and ethambutol, are applied in the treatment. The continuation phase take place at the next four months after initial treatment. It is oriented to the elimination of semi-dormant mycobacteria. Compared with bacteria at the beginning of the therapy, semi-dormant mycobacteria has a lower replication rate and may exist a low probability of antibactericidal resistance. A patient in continuous phase looks close like a healthy individual. However, without proper drug usage like stop applying drugs, drug resistance mycobacteria may regrow, making treatment become a challenge. The drug combinations commonly used in continuous stages are rifampin and isoniazid.       
The mode of action of rifampicin in M. tuberculosis is by binding to the β-subunit of the RNA polymerase, inhibiting the elongation of messenger RNA <ref>[https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4790366/ Blanchard JS, Review Molecular mechanisms of drug resistance in Mycobacterium tuberculosis doi: 10.3390/antibiotics3030317]</ref>isoniazid acts by inhibiting the synthesis of mycolic acids through the NADH-dependent enoyl-acyl carrier protein (ACP)-reductase, encoded by inhA <ref>[https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4790366/ Blanchard JS, Review Molecular mechanisms of drug resistance in Mycobacterium tuberculosis doi: 10.3390/antibiotics3030317]</ref>


[[Image:Temperature2.png|thumb|300px|right|<b>Figure 11: </b>The diplopterols (indicated as green molecules) migrate in POPC simulated cell membranes (indicated as orange sphere and gray sticks).<ref name = Caron2014/>]]
==Bacillus Calmette–Guérin (BCG) vaccination==
Different hopanoid lipids show different influences on membrane fluidity and permeability. Bile salts show no negative influence on the majority of the Gram-negative bacteria because these chemical compounds are not able to transfer across the outer membrane of the Gram-negative bacteria. Mutated bacteria, without the protection of hopanoid lipids, are vulnerable to the high bile salt conditions.<ref name =Welander2009/> However, different mutations in the same bacteria species show different levels of bile salts sensitivities. <i>shc</i> gene codes for the production of most hopanoid lipids. The <i>[[Rhodopseudomonas palustris]]</i> with this mutation shows no bile salts tolerance (<b>Figure 10</b>).<ref name = Welander2009>[http://jb.asm.org/content/191/19/6145.full.pdf+html Welander P. V., Hunter R. C., Zhang L., Sessions A. L., Summons R. E., and Newman D. K.. 2009. Hopanoids Play a Role in Membrane Integrity and pH Homeostasis in <i>Rhodopseudomonas palustris</i> TIE-1. JOURNAL OF BACTERIOLOGY, Oct. 2009, Vol. 191, No. 19, p. 6145–6156.]</ref> The <i>hpnH </i>mutation causes the deficient production of diploptenes and diplopterols. <i>[[Rhodopseudomonas palustris]]</i> with this mutation shows resistance towards the bile salts but perform a slower growth rate compared to that of the wild-type strain. The <i>hpnO</i> mutant cannot produce aminobacteriohopanetriols, one essential bacterial hopanoid lipid. This mutant shows no difference in bacterial growth and culture density in the high bile salts concentration compared to the wild-type strain.<ref name=Belin2018/><ref name=Welander2009/>
[[Image: 09.jpg|thumb|330px|left|Figure 6:</b> BCG vaccine .<ref>[https://www.museumofhealthcare.ca/explore/exhibits/vaccinations/other-vaccines.html]</ref>]]


===Orientation and distribution of hopanoid lipids===
===Molecular mechanism===
Until now, the only licensed vaccine against mycobacterium infection is Bacillus Calmette–Guérin (BCG) which is a lab cultured mycobacterium deriving from mycobacterium bovis(18).
Unlike other mycobacterium pathogens, BCG lacks virulence as it had a deletion of the RD-1 locus encode nine genes that include a 10-kDa cultured filtered protein (CFP-10) and a 6-kDa early secreted-antigen (ESTAT-6)<ref>[https://www.tandfonline.com/doi/full/10.1586/14760584.2016.1170599 Tamara Davenne a , * and Helen McShane Why don’t we have an effective tuberculosis vaccine yet? Expert Rev Vaccines. 2016 Aug 2; 15(8): 1009–1013.Published online 2016 May 3. doi: 10.1586/14760584.2016.1170599]</ref>. These two proteins are secreted by the Snm system and both play an essential role in regulating the virulence of pathogens. ESAT-6 is capable of blocking the toll-like receptor 2 (TLR2) that is a surface protein mediating the production of cytokines necessary for the development of effective immunity. Besides, CFP/ESTAT complex was also shown to downregulate reactive oxygen species (ROS) production <ref> [https://www.ncbi.nlm.nih.gov/pubmed/17557817 de Jonge MI, Pehau-Arnaudet G, Fretz MM, et al. ESAT-6 from Mycobacterium tuberculosis dissociates from its putative chaperone CFP-10 under acidic conditions and exhibits membrane-lysing activity. J Bacteriol. 2007;189(16):6028–6034.DOI: 10.1128/JB.00469-07]</ref>
. With the lack of expression of CFP-10 and ESAT-6, mycobacterium bovis in the BCG vaccine failed to counteract and damage the host cell system, allowing it to be killed by the immune system efficiently.


The orientation and the distribution of hopanoid lipids contribute to the bacterial heat resistance. Bacteria, with the help of high concentration of hopanoid lipids, obtain heat protections and keep the homeostasis of their cytoplasm. As the environmental temperature increases, the hopanoid lipids tend to move between two leaflets. In the lipid dynamic simulation at room temperature (298 K), most of the diplopterol molecules gather between the head and the tail of phospholipids. Thus, at milder temperature, the distribution of hopanoid lipids shows a large separation. However, as the temperature increases, the diplopterol molecules migrate to the empty spaces between the tails of two leaflets, largely increasing the thickness of the bacterial membranes and creating substantial protections for thermophiles (<b>Figure 11</b>).<ref name = Caron2014>[https://pubs.acs.org/doi/pdf/10.1021/jz5020778 Caron B., Mark A. E., and Poger D.. 2014. Some Like It Hot: The Effect of Sterols and Hopanoids on Lipid Ordering at High Temperature. J. Phys. Chem. Lett. 2014, 5, 3953−3957.]</ref>
===Vaccine limitation===
Although BCG is the most widely used vaccine in preventing tuberculosis in the world, it is the most controversial in current use. According to the World Health Organization, the estimation of  BCG against pulmonary infection varied from 0% to 80% <ref>[https://www.thelancet.com/journals/lancet/article/PIIS0140-6736(95)92348-9/fulltextP.E.M.Variation in protection by BCG: implications of and for heterologous immunity Communicable Disease Epidemiology Unit, London School of Hygiene and Tropical Medicine, London https://doi.org/10.1016/S0140-6736(95)92348-9]</ref>The reason to cause this high variability is unclear but it is highly associated with genetic nutrient differences between populations, and environmental factors such as sunlight exposure, poor cold-chain maintenance, or exposure to environmental mycobacterium tuberculosis infection<ref>[https://www.thelancet.com/journals/lancet/article/PIIS0140-6736(95)92348-9/fulltextP.E.M.Variation in protection by BCG: implications of and for heterologous immunity Communicable Disease Epidemiology Unit, London School of Hygiene and Tropical Medicine, London https://doi.org/10.1016/S0140-6736(95)92348-9]</ref>
. Therefore, the age of the person and the frequency of BCG vaccination has always varied from country to country. The world health organization is currently recommended BCG vaccination to all countries with a high incidence of TB, such as China and India. Massive immunization has never been used in low TB outbreak rate countries such as the United States<ref>[https://apps.who.int/iris/handle/10665/260307World Health Organization = Organisation mondiale de la Santé. (‎2018)‎. BCG vaccines: WHO position paper – February 2018 – Vaccins BCG: Note de synthèse de l’OMS – Février 2018. Weekly Epidemiological Record = Relevé épidémiologique hebdomadaire, 93 (‎08)‎, 73 - 96. World Health Organization = Organisation mondiale de la Santé.]</ref>.


[[Image:Hopaanti.png|thumb|300px|left|<b>Figure 12:</b> The <i>shc</i> mutant strain shows an increased detergent sensitivity compared to the wild-type.<ref name = Saenz2015/>]][[Image:NPN.png|thumb|300px|right|<b>Figure 13:</b> The intracellular concentration of NPN of the <i>shc</i> mutant strain does not change a lot, while that of the wild-type strain decreases constantly.<ref name = Saenz2015/>]]
===BCG vaccination could train the innate immune system===
 
Beside having high variability in against TB infection, BCG was observed to have a non-specific effect in targeting other pathogens. It was shown that macrophage pre-exposed to BCG displayed an increase in PMA-induced production of H2O2 and enhanced phagocytosis <ref>[https://www.ncbi.nlm.nih.gov/pubmed/1439583 Van ‘t Wout JW, Poell R, Van Furth R. The role of BCG/PPD-activated macrophages in resistance against systemic candidiasis in mice.Scand J Immunol. 1992;36(5):713–719 DOI: 10.1111/j.1365-3083.1992.tb03132.x]</ref>. The recent study even show that BCG is promising treatment in against COVID-19 outbreak by indirectly boost the innate immune system <ref>[https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7136957/ Medical Hypotheses (nih.gov), Medical Hypotheses (6 April 2020). "Is Global BCG Vaccination Coverage Relevant to the Progression Of SARS-CoV-2 Pandemic?". PMC 7136957doi: 10.1016/j.mehy.2020.109707 </ref>.
===Cooperation with bacterial membrane proteins===
 
Hopanoid lipids might cooperate with outer membrane proteins.<ref name=Belin2018/>  The <i>[[Methylobacterium]] extorquens </i>mutant strain, with a non-functional hopanoid lipid production, shows an increased detergent sensitivity (<b>Figure 12</b>). Additionally, this strain perhaps cannot pump out the antibiotics due to its non-functional efflux. Researchers studied the accumulation of 1-N-phenylnaphthylamine (NPN), one type of lipophilic dye, in <i>[[Methylobacterium]] extorquens</i>. The wild-type strain constantly pumped out NPN, and therefore the intracellular concentration of PNP kept decreasing. However, the intracellular concentration of <i>shc</i> mutant did not change a lot, indicating that perhaps the mutant had deficient efflux (<b>Figure 13</b>).<ref name=Saenz2015/> Thus, the hopanoid lipids might contribute and assist the functions of membrane proteins.<ref name=Belin2018/> The collaboration of the hopanoid lipids and membrane proteins enhances bacterial resistance and helps bacteria to maintain the homeostasis between the cytoplasm and extracellular environment. Additionally, bacterial membranes, one of the most significant energy production places, require the presence of effective hopanoid lipids to achieve energy production and storage. <i>[[Nostoc punctiforme]]</i>, with a hopanoid lipid mutation, show a decrease in energy storage compared to that of the wild-type strain.<ref name=Belin2018/>
 
The function of hopanoids is more significant in the stress-resistance specified cells. The filaments of <i>[[Nostoc punctiforme]]</i>, one kind of filamentous cyanobacteria, are constituted by the vegetative cells. That specified cells conduct photosynthesis under the environment with abundant nutrients. Therefore, they fix carbon dioxide, showing a high growth and reproduction rate. In these photosynthetic cells, the hopanoid concentration has negligible influence on the stress response. However, under the environment with poor nutrient concentration, <i>[[Nostoc punctiforme]]</i> develop the akinete cells through differentiation, which contain higher resistance toward the cold and dry conditions. The akinete cells keep their cellular structure and bacterial activity. They also stay in low energy consumption until they encounter an environment with rich resources. In the akinete cells, a high concentration of hopanoid lipids is detected in bacterial membranes. Previous studies found that the mutant without functional hopanoid lipid showed less resistance to the extracellular resistance. Similarly, <i>[[Streptomyces coelicolor]]</i>, one Gram-positive soil bacteria species, forms vegetative cells under nutrient-rich environment. These vegetative cells have a low hopanoid lipid concentration. However, at the end of their life cycle, they produce and accumulate hopanoid lipids, forming spore via sporulation, which can assist their resistance under the extreme conditions.<ref name = Belin2018/>
 
==Nitrogen fixation==
[[Image:Nitrogenfix.jpg|thumb|100px|right|<b>Figure 14:</b> The nodules formed by wild-tryp, <i>hpnP</i>, and <i>hpnH</i> strains. Compared to the wild-type <i>B. diazoefficiens</i>, the nodules formed by either <i>hpnP</i> or <i>hpnH</i> strain are unhealthy.<ref name = Kulkarni2013/>]]
Various bacteria, with the ability to produce hopanoids, can fix nitrogen. Bacteria, such as <i>Beijerinckia, [[Frankia]], [[Anabaena]], [[Burkholderia]]</i>, etc., show a positive correlation between the hopanoid production and nitrogen fixation.<ref name=Belin2018/> Most nitrogen-fixing bacteria live in close physical correlations with plants, such as alfalfa, soil beans, peas, etc. Both bacteria and plants can take advantage of this relationship. <i>[[Bradyrhizobium]]</i> spp. derive energy and other important chemical cofactors from their host plants. The plants also can protect bacteria from stress from the environments, such as competitions with other microbiomes, high proton concentration, etc. Equally, plants benefit from the nitrogen oxides produced by the nitrogen-fixing bacteria, and therefore plants show an enhanced growth rate and outcompete their competitors. There are also free-living nitrogen-fixing microbes, such as <i>[[Anabaena]] </i>spp.,<i> [[Frankia]]</i> spp., etc. However, most of those bacteria do not fix nitrogen without coexisting with plants.
 
The <b>legume-rhizobia root nodule symbiosis</b> is among one of the most widely studied plants and bacteria associations. The production of hopanoid lipids influences the bacterial symbiosis with the host plants. The<i> [[Bradyrhizobium]]</i> spp., with <i>shc </i>mutation, produce a negligible amount of hopanoid lipids. Therefore, this bacteria strain is incapable of integrating with plants. Additionally, different types of hopanoid lipid contribute differently to the bacterial associations with plants. The <i>[[Bradyrhizobium]] diazoefficiens </i>with a <i>hpnP </i>mutation cannot produce the extended hopanoids. Their association with the <i>Aeschynomene afraspera </i>results in morphologically disorganized nodules. The <i>Aeschynomene afraspera</i> shows nitrogen starvation, indicating a decreased nitrogen-fixing ability of the <i>hpnP </i>mutant. However, the <i>hpnH </i>mutant, which have less production of 35 carbon hopanoids, cannot form a mature nodule (<b>Figure 14</b>).<ref name = Kulkarni2013>[http://mbio.asm.org/content/6/5/e01251-15.full.pdf+html Kulkarni G., Busset N., Molinaro A., Gargani D., Chaintreuil C., Silipo A., Giraud E., and Newman D. K.. 2015. Specific Hopanoid Classes Differentially Affect Free-Living and Symbiotic States of Bradyrhizobium diazoefficiens. mBio 6(5):e01251-15. doi:10.1128/mBio.01251-15.]</ref>.
 
The presence of the hopanoid lipids might also contribute to the competition between bacteria to inhabit the hosts. The mutation strain <i>shc</i>, which produces no hopanoid lipids shows an inability in long-term colonization of a plant. Previous studies found that in the beginning, <i>shc</i> mutant grew and developed in host normally. However, after a few days, it started to degenerate and be recycled by its host. On the other hand, the high concentration of hopanoid lipids increases bacterial stress tolerances. For example, the <i>[[Bradyrhizobium]]</i> and <i>[[Burkholderia]]</i>, both of which contain a high concentration of hopanoid lipids, show resistance to high temperature and low pH conditions. Therefore, in the consideration of global warming and increasing soil acidity, both bacteria might outcompete other bacteria in soil and plants.
 
[[Image:Oxyprotection.png|thumb|400px|left|<b>Figure 15:</b> Under the high concentration of oxygen, <i>[[Azotobacter]] vinelandii</i> also synthesize alginate to create an alginate capsule to protect nitrogenase activity.<ref name = Kulkarni2013/>]]
 
Most of the time, bacteria conduct nitrogen fixation in the low-oxygen concentration environment. <b>Nitrogenase</b>, the core enzyme in nitrogen fixation, is vulnerable in the presence of oxygen. Thus, most of the nitrogen-fixing bacteria exist under the anaerobic environment. Sometimes, nitrogen fixation can also be conducted at high oxygen concentration. Under this condition, bacteria need to develop more sophisticated mechanisms to protect the nitrogenase and achieve nitrogen fixation. The free-living nitrogen-fixing bacteria, <i>[[Azotobacter]] vinelandii</i>, develop various ways to fix nitrogen under high oxygen condition. For example, the <i>[[Azotobacter]] vinelandii</i> decrease its cellular surface area. Therefore, for each unit of cytoplasm, there are larger protections from the bacterial membranes. Also, under high oxygen condition, it also increased its oxygen consumption via keeping a high respiration rate, thus creating an optional anaerobic environment for nitrogen fixation. The <i>[[Azotobacter]] vinelandii</i> also synthesizes alginate to create an alginate capsule, a thick barrier which limits the oxygen fission and protects the nitrogenase from the high oxygen-concentrated surroundings. Under the lower oxygen concentrated environment, <i>[[Azotobacter]] vinelandii</i> develops a loose alginate capsule, while under the high concentration, it builds up a compact and thick alginate capsule (<b>Figure 15</b>). Additionally, when the bacteria interact with or inhabit plants, the host plants synthesize leghemoglobin molecules, one type of oxygen-transport metalloproteins. This hemoglobin scavenges oxygen from the root nodules of the leguminous plants, creating an optimal environment for nitrogenase activity<ref name = Sabra2000>[https://www.ncbi.nlm.nih.gov/pmc/articles/PMC92256/pdf/am004037.pdf Sabra W., Zeng A. P., Lunsdorf H., and Deckwer W. R.. 2000. Effect of Oxygen on Formation and Structure of Azotobacter vinelandii Alginate and Its Role in Protecting Nitrogenase. APPLIED AND ENVIRONMENTAL MICROBIOLOGY, Sept. 2000, Vol. 66, No. 9, p. 4037–4044]</ref>.
 
 
<br><br>Authored for BIOL 238 Microbiology, taught by [mailto:slonczewski@kenyon.edu Joan Slonczewski], 2018, [http://www.kenyon.edu/index.xml Kenyon College].

Latest revision as of 03:32, 17 May 2020

This is a curated page. Report corrections to Microbewiki.

By Boyu Yang

Introduction

Figure 1:
M. tuberculosis colonies.[1]
Figure 2: Location and structure of the Mycobacterium mycolic cell wall[2]

Mycobacterium tuberculosis(Figure.1) is a deadly human pathogen that has a staggering impact globally, causing infection disease called tuberculosis (TB). According to the Centers for Disease Control and Prevention, eight million people around the world become sick with TB and there are over two million TB-related deaths worldwide each year.[3] However, most of the infection is latent and only 5 to 10% of this population has a lifetime risk of developing active tuberculosis, either within 1 or 2 years after infection (primary tuberculosis) or thereafter (secondary tuberculosis) [4]


Mycobacterium tuberculosis is a weakly gram-positive, non-motile, rod-shaped bacterium. It is also a facultative intracellular parasite as well as an obligated aerobic. This explains why tuberculosis is a disease typically affects the lungs. Unlike other bacteria that have cell walls mainly composed of peptidoglycan, the major cell wall component of mycobacterium is lipids(Figure.2). The lipid layer makes it impervious for gram staining, and it shows either gram-positive or gram-negative. More advance methods like acid-fast staining applied to detect the function of Mycobacterium.[5]

Mycobacterium tuberculosis has a low generation time; cell division occurs every 18-24 hours, which is extremely slow compared with other bacteria that normally has a division rate every 20 minutes.[6] The reason is that the mycolic acid has a low permeability which can protects bacterium taking damage from the immune system such as phagosome and macrophage. However, the impervious characteristic also limits nutrient accessibility, decreasing the rate of diffusion and eventually leads to a slower growth rate.

Mycobacterium tuberculosis cell wall structure

Figure 3:Chemical structures of mycolic acids from M. tuberculosis. There are five forms of mycolic acids in M. tuberculosis, illustrated with α-mycolic acid from the H37Ra strain and methoxy- and keto-mycolic acids from M. tuberculosis subsp. hominis strains DT, PN, and C. Both cyclopropane rings in α-mycolic acid have the cis configuration. The methoxy- and keto-mycolic acids can have either the cis or trans configuration on the proximal cyclopropane ring.[7]
Figure 4: The general structure of Cord Factor.[8]

Mycolic acid

Mycolic acids,2-alkyl, 3-hydroxy long-chain fatty acids (FAs), are major and specific lipid components of the mycobacterial cell envelope that account for up to 60% of the whole cell dry weight. They are essential for the survival of members of the genus Mycobacterium.[9]In Mycobacterium tuberculosis cell wall, Mycolic acid can be divided into three categories: alpha-myolic acid, methoxyl-myolic acid, and ketone-myolic acid (figure.3). Alpha-mycolic acid has composed more than 70% of the mycolic acid in M. tuberculosis. It is a pure long alkyl chain attached with several cyclopropanes that contribute to the structural integrity of the cell wall complex and protect the bacillus from oxidative stress.[10] Methoxyl-myolic acid made up to 10% to 15% of the mycolic acid. It has extra methoxyl group connected with fatty acid chain. The rest of the 10% to 15% mycolic acid is ketone mycolic acid which has some extra ketone groups attached on fatty acid.[11] Deletion of those cyclopropane rings would lead to significant attenuation in growth and deletion of the keto-mycolates would lead to restricted growth in macrophages.[12] Thus it is highly associated with virulence of Mycobacterium tuberculosis.

The presence of mycolic plays a significant role in obstructing hydrophilic antimicrobials.[13] Because of this property, hydrophobic antibiotic like rifampicin and fluoroquinolones may be able to cross the cell wall by diffusion. However, the majority of the hydrophilic nutrients and antibiotics like isoniazid are not to diffuse through the lipid layer and they are considered to porin channel instead.[14] Mycobacterium tuberculosis has less abundant than other bacteria and allow a slow uptake rate of nutrient and antibiotic, making it highly resistant to all kinds of antibiotic. Besides resistance to antibiotics, hydrophobic mycolic cell wall also enables tuberculosis to survive inside the macrophage by inhibiting the action of cation proteins, lysozymes, and oxygen radicals, hiding them from the host immune system.

Cord factors

Cord factors (trehalose 6,6′-dimycolate; TDM)is a glycolipid molecule also presence in the cell wall of mycobacterium (figure.3). It locates at the exterior parts of the cell wall and influences the arrangement of mycobacterium into long rod shape, giving it name.[15]

Cord factor is formed by a trehalose sugar and a disaccharide that esterified to two mycolic acid (Figure 4).[16] One of the monosaccharides is connected with mycolic acid at its six carbon and the other monosaccharides also connected with mycolic acid at its six-carbon.[17] Thus, it is named as trehalose 6,6-dimycolate.

Cord factor is extremely toxic to mammalian and it can inhibit polymorphonuclear cell, a category of white blood cells with varying shape of nucleus, migration to the affected area where the infection is present.(10.5) Cord factor could also stimulate the production of TNF (tumor necrosis factors) secretion from the macrophage and T cell. This would lead to a low-grade fever in the infected individuals following by anorexia and eventually result in weight loss. Furthermore, cord factor can induce granuloma formation by its ability to stimulate cytokine production from inflammatory cells in the host.[18]

Wax-D

Wax-D is a lipid complex composed by LAM, sulfatides, and glycolipids and it presents an essential role in preventing oxidation burst inside the phagosome. Sulfatides and glycolipids help mycobacterium tuberculosis in attaching to the macrophages and thusinhibiting the phagosome lysosome fusion. Wax-D also regulates internal acidity by preventing hydrogen ion entering the phagosome, ensuring its DNA replication.[19]

Clinical behavior

Figure 5: Granuloma of Tuberculosis. Arrows pointed at multi-nucleated giant cells.[20]


Primary infection

Primary infection, the initial phase, occurs in people without specific immunity, generally normal children and young adults who have not previously been exposed to Mycobacterium tuberculosis.[21] It occur when the inhaled bacteria enter the lung would enter the terminal air space and replicate at alveolar macrophage.[22] Some of the infected macrophage would migrate to the close lymph node, and eventually disseminate the infection to remote body parts. Primary infection can be tested by observing the present of granuloma, collection of macrophage ,at the infected area (Figure 5). Primary infection can developed into either latent infection or progressive primary infection. Latent infection take place when the M. tuberculosis have been eliminated by the innate immune system or switch into dormant stage and it is hard to differentiate those two stage based on x ray. Progressive primary infection is observed in 5-10% of patients with primary tuberculosis. Just as its name, the infection gradually worsen and worsen at the 1-2 year of the infection. This infection is developed when the immune system failed to control the out break of virus and it is usually happens at the newborn infant whose immune system is underdeveloped[21].

secondary infection

Secondary infection represent the reactivation of a prior latent or dormant infection and there are 5% to 10% of the secondary infection developed from the latent infection. Secondary infection could occur at any point of the host life, either in several months to decades. There are many factors that governs the occurrence of secondary infection, including the immune state of the host. When the host has experience immunity depression, their likelihood to have a secondary infection is high. Secondary infection is alway with other factors. Patients coinfected with Human immunodeficiency virus (HIV), organ transplant, and IVDU have more than 10-fold risk than the general population. Besides reactivation, secondary infection can also be caused by reinfection through bacteria outside the host.

treatment and prevention

Figure 6: The Infection Mechanism of Mycobacterium tuberculosis[23]

Medical treatment of tuberculosis, together with correct diagnosis, plays an essential in the management and control of tuberculosis. [24]Until now, there are no specific single drugs to eliminate mycobacterium tuberculosis. A combination of two stage multiple stage drug therapy is the most common method used on tuberculosis treatment. Adherence to long-term antituberculosis therapy is crucial for maintaining adequate blood drug level and drug resistance can easily evolve from mycobacterium tuberculosis if the patients apply durg inadequately [25]


In general, there are two different steps in the treatment of tuberculosis can be recognized, the initial (bactericidal) phase and the continuation (sterilizing) phase. The initial phase treatment usually takes place at the first two month of the treatment in which mycobacteria with a high replication rate are killed, and, consequently, with the histological pulmonary restoration and the reduction of the inflammation process, symptoms and clinical signs resolve (clinical recovery) [26] The initial phase is also known as intensive phase as most of the drugs like , rifampin, Isoniazid, pyrazinamide, and ethambutol, are applied in the treatment. The continuation phase take place at the next four months after initial treatment. It is oriented to the elimination of semi-dormant mycobacteria. Compared with bacteria at the beginning of the therapy, semi-dormant mycobacteria has a lower replication rate and may exist a low probability of antibactericidal resistance. A patient in continuous phase looks close like a healthy individual. However, without proper drug usage like stop applying drugs, drug resistance mycobacteria may regrow, making treatment become a challenge. The drug combinations commonly used in continuous stages are rifampin and isoniazid. The mode of action of rifampicin in M. tuberculosis is by binding to the β-subunit of the RNA polymerase, inhibiting the elongation of messenger RNA [27]isoniazid acts by inhibiting the synthesis of mycolic acids through the NADH-dependent enoyl-acyl carrier protein (ACP)-reductase, encoded by inhA [28]

Bacillus Calmette–Guérin (BCG) vaccination

Figure 6: BCG vaccine .[29]

Molecular mechanism

Until now, the only licensed vaccine against mycobacterium infection is Bacillus Calmette–Guérin (BCG) which is a lab cultured mycobacterium deriving from mycobacterium bovis(18). Unlike other mycobacterium pathogens, BCG lacks virulence as it had a deletion of the RD-1 locus encode nine genes that include a 10-kDa cultured filtered protein (CFP-10) and a 6-kDa early secreted-antigen (ESTAT-6)[30]. These two proteins are secreted by the Snm system and both play an essential role in regulating the virulence of pathogens. ESAT-6 is capable of blocking the toll-like receptor 2 (TLR2) that is a surface protein mediating the production of cytokines necessary for the development of effective immunity. Besides, CFP/ESTAT complex was also shown to downregulate reactive oxygen species (ROS) production [31] . With the lack of expression of CFP-10 and ESAT-6, mycobacterium bovis in the BCG vaccine failed to counteract and damage the host cell system, allowing it to be killed by the immune system efficiently.

Vaccine limitation

Although BCG is the most widely used vaccine in preventing tuberculosis in the world, it is the most controversial in current use. According to the World Health Organization, the estimation of BCG against pulmonary infection varied from 0% to 80% [32]The reason to cause this high variability is unclear but it is highly associated with genetic nutrient differences between populations, and environmental factors such as sunlight exposure, poor cold-chain maintenance, or exposure to environmental mycobacterium tuberculosis infection[33] . Therefore, the age of the person and the frequency of BCG vaccination has always varied from country to country. The world health organization is currently recommended BCG vaccination to all countries with a high incidence of TB, such as China and India. Massive immunization has never been used in low TB outbreak rate countries such as the United States[34].

BCG vaccination could train the innate immune system

Beside having high variability in against TB infection, BCG was observed to have a non-specific effect in targeting other pathogens. It was shown that macrophage pre-exposed to BCG displayed an increase in PMA-induced production of H2O2 and enhanced phagocytosis [35]. The recent study even show that BCG is promising treatment in against COVID-19 outbreak by indirectly boost the innate immune system [36].

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