Gram-positive bacteria

Rod-shaped gram-positive Bacillus anthracis bacteria in a cerebrospinal fluid sample stand out from round white blood cells.
Violet stained gram-positive cocci and pink stained gram-negative rod-shaped bacteria

Gram-positive bacteria are bacteria that give a positive result in the Gram stain test. Gram-positive bacteria take up the crystal violet stain used in the test, and then appear to be purple-coloured when seen through a microscope. This is because the thick peptidoglycan layer in the bacterial cell wall retains the stain after it is washed away from the rest of the sample, in the decolorization stage of the test.

Gram-negative bacteria cannot retain the violet stain after the decolorization step; alcohol used in this stage degrades the outer membrane of gram-negative cells making the cell wall more porous and incapable of retaining the crystal violet stain. Their peptidoglycan layer is much thinner and sandwiched between an inner cell membrane and a bacterial outer membrane, causing them to take up the counterstain (safranin or fuchsine) and appear red or pink.

Despite their thicker peptidoglycan layer, gram-positive bacteria are more receptive to antibiotics than gram-negative, due to the absence of the outer membrane.

Characteristics

Gram-positive and -negative cell wall structure
Structure of gram-positive cell wall

In general, the following characteristics are present in gram-positive bacteria:[1]

  1. Cytoplasmic lipid membrane
  2. Thick peptidoglycan layer
  3. Teichoic acids and lipoids are present, forming lipoteichoic acids, which serve as chelating agents, and also for certain types of adherence.
  4. Peptidoglycan chains are cross-linked to form rigid cell walls by a bacterial enzyme DD-transpeptidase.
  5. A much smaller volume of periplasm than that in gram-negative bacteria.

Only some species have a capsule usually consisting of polysaccharides. Also only some species are flagellates, and when they do have flagella they only have two basal body rings to support them (gram-negative have four). Both gram-positive and gram-negative bacteria commonly have a surface layer called an S-layer. In gram-positive bacteria, the S-layer is attached to the peptidoglycan layer (in gram-negative bacteria, the S-layer is attached directly to the outer membrane). Specific to gram-positive bacteria is the presence of teichoic acids in the cell wall. Some of these are lipoteichoic acids, which have a lipid component in the cell membrane that can assist in anchoring the peptidoglycan.[2]

Classification

Along with cell shape, Gram staining is a rapid method used to differentiate bacterial species. In traditional and even some areas of contemporary microbiological practice, such staining, alongside growth requirement and antibiotic susceptibility testing, and other macroscopic and physiologic tests, forms the full basis for classification and subdivision of the bacteria (e.g., see figure and pre-1990 versions of Bergey's Manual).

Species identification hierarchy in clinical settings

Historically, the kingdom Monera was divided into four divisions based primarily on Gram staining: Firmicutes (positive in staining), Gracilicutes (negative in staining), Mollicutes (neutral in staining) and Mendocutes (variable in staining).[3] Based on 16S ribosomal RNA phylogenetic studies of the late microbiologist Carl Woese and collaborators and colleagues at the University of Illinois, the monophyly of the gram-positive bacteria was challenged,[4] with striking productive implications for the therapeutic and general study of these organisms. Based on molecular studies of the 16S sequences, Woese recognised twelve bacterial phyla, two being gram-positive: high-GC gram-positives (the Actinobacteria) and low-GC gram-positives (the Firmicutes), (where G and C refer to the guanine and cytosine content in their genomes).[4] The high GC gram-positives the Actinobacteria include the Corynebacterium, Mycobacterium, Nocardia and Streptomyces genera. The low-GC gram-positive Firmicutes, have a 45–60% GC content, but this is lower than that of the Actinobacteria.[1]

Importance of the outer cell membrane in bacterial classification

The structure of peptidoglycan, composed of N-acetylglucosamine and N-acetylmuramic acid

Although bacteria are traditionally divided into two main groups, gram-positive and gram-negative, based on their Gram stain retention property, this classification system is ambiguous as it refers to three distinct aspects (staining result, envelope organization, taxonomic group), which do not necessarily coalesce for some bacterial species.[5][6][7][8] The gram-positive and gram-negative staining response is also not a reliable characteristic as these two kinds of bacteria do not form phylogenetic coherent groups.[5] However, although Gram staining response is an empirical criterion, its basis lies in the marked differences in the ultrastructure and chemical composition of the bacterial cell wall, marked by the absence or presence of an outer lipid membrane.[5][9]

All gram-positive bacteria are bounded by a single-unit lipid membrane, and, in general, they contain a thick layer (20–80 nm) of peptidoglycan responsible for retaining the Gram stain. A number of other bacteria—that are bounded by a single membrane, but stain Gram-negative due to either lack of the peptidoglycan layer, as in the Mycoplasmas, or their inability to retain the Gram stain because of their cell wall composition—also show close relationship to the Gram-positive bacteria. For the bacterial cells bounded by a single cell membrane, the term "monoderm bacteria" or "monoderm prokaryotes" has been proposed.[5][9]

In contrast to gram-positive bacteria, all archetypical gram-negative bacteria are bounded by a cytoplasmic membrane and an outer cell membrane; they contain only a thin layer of peptidoglycan (2–3 nm) between these membranes. The presence of inner and outer cell membranes defines a new compartment in these cells: the periplasmic space or the periplasmic compartment. These bacteria have been designated as "diderm bacteria."[5][9] The distinction between the monoderm and diderm bacteria is supported by conserved signature indels in a number of important proteins (viz. DnaK, GroEL).[5][6][9][10] Of these two structurally distinct groups of bacteria, monoderms are indicated to be ancestral. Based upon a number of observations including that the gram-positive bacteria are the major producers of antibiotics and that, in general, gram-negative bacteria are resistant to them, it has been proposed that the outer cell membrane in gram-negative bacteria (diderms) has evolved as a protective mechanism against antibiotic selection pressure.[5][6][9][10] Some bacteria, such as Deinococcus, which stain gram-positive due to the presence of a thick peptidoglycan layer and also possess an outer cell membrane are suggested as intermediates in the transition between monoderm (gram-positive) and diderm (gram-negative) bacteria.[5][10] The diderm bacteria can also be further differentiated between simple diderms lacking lipopolysaccharide, the archetypical diderm bacteria where the outer cell membrane contains lipopolysaccharide, and the diderm bacteria where outer cell membrane is made up of mycolic acid.[7][10][11]

Exceptions

In general, gram-positive bacteria are monoderms and have a single lipid bilayer whereas gram-negative bacteria are diderms and have two bilayers. Some taxa lack peptidoglycan (such as the domain Archaea, the class Mollicutes, some members of the Rickettsiales, and the insect-endosymbionts of the Enterobacteriales) and are gram-variable. This, however, does not always hold true. The Deinococcus-Thermus bacteria have gram-positive stains, although they are structurally similar to gram-negative bacteria with two layers. The Chloroflexi have a single layer, yet (with some exceptions[12]) stain negative.[13] Two related phyla to the Chloroflexi, the TM7 clade and the Ktedonobacteria, are also monoderms.[14][15]

Some Firmicute species are not gram-positive. These belong to the class Mollicutes (alternatively considered a class of the phylum Tenericutes), which lack peptidoglycan (gram-indeterminate), and the class Negativicutes, which includes Selenomonas and stain gram-negative.[11] Additionally, a number of bacterial taxa (viz. Negativicutes, Fusobacteria, Synergistetes, and Elusimicrobia) that are either part of the phylum Firmicutes or branch in its proximity are found to possess a diderm cell structure.[8][10][11] However, a conserved signature indel (CSI) in the HSP60 (GroEL) protein distinguishes all traditional phyla of gram-negative bacteria (e.g., Proteobacteria, Aquificae, Chlamydiae, Bacteroidetes, Chlorobi, Cyanobacteria, Fibrobacteres, Verrucomicrobia, Planctomycetes, Spirochetes, Acidobacteria, etc.) from these other atypical diderm bacteria, as well as other phyla of monoderm bacteria (e.g., Actinobacteria, Firmicutes, Thermotogae, Chloroflexi, etc.).[10] The presence of this CSI in all sequenced species of conventional LPS (lipopolysaccharide)-containing gram-negative bacterial phyla provides evidence that these phyla of bacteria form a monophyletic clade and that no loss of the outer membrane from any species from this group has occurred.[10]

Pathogenesis

Colonies of a gram-positive pathogen of the oral cavity, Actinomyces sp.

In the classical sense, six gram-positive genera are typically pathogenic in humans. Two of these, Streptococcus and Staphylococcus, are cocci (sphere-shaped). The remaining organisms are bacilli (rod-shaped) and can be subdivided based on their ability to form spores. The non-spore formers are Corynebacterium and Listeria (a coccobacillus), whereas Bacillus and Clostridium produce spores.[16] The spore-forming bacteria can again be divided based on their respiration: Bacillus is a facultative anaerobe, while Clostridium is an obligate anaerobe.[17] Also, Rathybacter, Leifsonia, and Clavibacter are three gram-positive genera that cause plant disease. Gram positive bacteria are capable of causing serious and sometimes fatal infections in newborn infants.[18]

Orthographic note

The adjectives 'gram-positive' and 'gram-negative' are named after Hans Christian Gram; as eponymous adjectives, they are conventionally written in lowercase.[19][20][21]

References

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  3. Gibbons, N. E.; Murray, R. G. E. (1978). "Proposals Concerning the Higher Taxa of Bacteria". IJSEM 28 (1): 1–6. doi:10.1099/00207713-28-1-1.
  4. 1 2 Woese, C. R. (1987). "Bacterial evolution". Microbiological reviews 51 (2): 221–271. PMC 373105. PMID 2439888.
  5. 1 2 3 4 5 6 7 8 Gupta, R.S. (1998). "Protein phylogenies and signature sequences: A reappraisal of evolutionary relationships among archaebacteria, eubacteria and eukaryotes". Microbiol. Mol. Biol. Rev. 62: 1435–1491.
  6. 1 2 3 Gupta, R.S. (2000). "The natural evolutionary relationships among prokaryotes". Crit. Rev. Microbiol 26: 111–131. doi:10.1080/10408410091154219. PMID 10890353.
  7. 1 2 Desvaux, M; Hébraud, M; Talon, R; Henderson, IR (2009). "Secretion and subcellular localizations of bacterial proteins: a semantic awareness issue". Trends Microbiol 17: 139–145. doi:10.1016/j.tim.2009.01.004. PMID 19299134.
  8. 1 2 Sutcliffe, IC (2010). "A phylum level perspective on bacterial cell envelope architecture". Trends Microbiol 18: 464–470. doi:10.1016/j.tim.2010.06.005. PMID 20637628.
  9. 1 2 3 4 5 Gupta, R. S. (1998). "What are archaebacteria: life's third domain or monoderm prokaryotes related to gram-positive bacteria? A new proposal for the classification of prokaryotic organisms". Molecular Microbiology 29 (3): 695–707. doi:10.1046/j.1365-2958.1998.00978.x. PMID 9723910.
  10. 1 2 3 4 5 6 7 Gupta, R. S. (2011). "Origin of diderm (gram-negative) bacteria: antibiotic selection pressure rather than endosymbiosis likely led to the evolution of bacterial cells with two membranes". Antonie van Leeuwenhoek 100: 171–182. doi:10.1007/s10482-011-9616-8. PMC 3133647. PMID 21717204.
  11. 1 2 3 Marchandin, H.; Teyssier, C.; Campos, J.; Jean-Pierre, H.; Roger, F.; Gay, B.; Carlier, J. -P.; Jumas-Bilak, E. (2009). "Negativicoccus succinicivorans gen. Nov., sp. Nov., isolated from human clinical samples, emended description of the family Veillonellaceae and description of Negativicutes classis nov., Selenomonadales ord. Nov. And Acidaminococcaceae fam. Nov. In the bacterial phylum Firmicutes". International Journal of Systematic and Evolutionary Microbiology 60 (6): 1271–1279. doi:10.1099/ijs.0.013102-0. PMID 19667386.
  12. Yabe, S.; Aiba, Y.; Sakai, Y.; Hazaka, M.; Yokota, A. (2010). "Thermogemmatispora onikobensis gen. nov., sp. nov. And Thermogemmatispora foliorum sp. nov., isolated from fallen leaves on geothermal soils, and description of Thermogemmatisporaceae fam. Nov. And Thermogemmatisporales ord. Nov. Within the class Ktedonobacteria". International Journal of Systematic and Evolutionary Microbiology 61 (4): 903–910. doi:10.1099/ijs.0.024877-0. PMID 20495028.
  13. Sutcliffe, I. C. (2011). "Cell envelope architecture in the Chloroflexi: A shifting frontline in a phylogenetic turf war". Environmental Microbiology 13 (2): 279–282. doi:10.1111/j.1462-2920.2010.02339.x. PMID 20860732.
  14. Hugenholtz, P.; Tyson, G. W.; Webb, R. I.; Wagner, A. M.; Blackall, L. L. (2001). "Investigation of Candidate Division TM7, a Recently Recognized Major Lineage of the Domain Bacteria with No Known Pure-Culture Representatives". Applied and Environmental Microbiology 67 (1): 411–419. doi:10.1128/AEM.67.1.411-419.2001. PMC 92593. PMID 11133473.
  15. Cavaletti, L.; Monciardini, P.; Bamonte, R.; Schumann, P.; Rohde, M.; Sosio, M.; Donadio, S. (2006). "New Lineage of Filamentous, Spore-Forming, Gram-Positive Bacteria from Soil". Applied and Environmental Microbiology 72 (6): 4360–4369. doi:10.1128/AEM.00132-06. PMC 1489649. PMID 16751552.
  16. Gladwin, Mark; Bill Trattler (2007). Clinical Microbiology made ridiculously simple. Miami, FL: MedMaster, Inc. pp. 4–5. ISBN 978-0-940780-81-1.
  17. Sahebnasagh R, Saderi H, Owlia P. Detection of methicillin-resistant Staphylococcus aureus strains from clinical samples in Tehran by detection of the mecA and nuc genes. The First Iranian International Congress of Medical Bacteriology; 4–7 September; Tabriz, Iran. 2011. 195 pp.
  18. MacDonald, Mhairi (2015). Avery's neonatology : pathophysiology and management of the newborn. Philadelphia: Wolters Kluwer. ISBN 9781451192681; Access provided by the University of Pittsburgh
  19. Centers for Disease Control and Prevention. Emerging Infectious Diseases Journal Style Guide. Preferred Usage
  20. Merriam-Webster, Merriam-Webster's Medical Dictionary, Merriam-Webster.
  21. Elsevier, Dorland's Illustrated Medical Dictionary, Elsevier.

External links

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