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Gram stain

February 15, 2024

Gram stain (Gram staining or Gram's method), is a method of staining used to classify bacterial species into two large groups: gram-positive bacteria and gram-negative bacteria. It may also be used to diagnose a fungal infection.[1] The name comes from the Danish bacteriologist Hans Christian Gram, who developed the technique in 1884.[2]

Micrograph of a gram-positive coccus and a gram-negative rod.
A Gram stain of mixed Staphylococcus aureus (S. aureus ATCC 25923, gram-positive cocci, in purple) and Escherichia coli (E. coli ATCC 11775, gram-negative bacilli, in red), the most common Gram stain reference bacteria

Gram staining differentiates bacteria by the chemical and physical properties of their cell walls. Gram-positive cells have a thick layer of peptidoglycan in the cell wall that retains the primary stain, crystal violet. Gram-negative cells have a thinner peptidoglycan layer that allows the crystal violet to wash out on addition of ethanol. They are stained pink or red by the counterstain,[3] commonly safranin or fuchsine. Lugol's iodine solution is always added after addition of crystal violet to strengthen the bonds of the stain with the cell membrane.

Gram staining is almost always the first step in the identification of a bacterial group. While Gram staining is a valuable diagnostic tool in both clinical and research settings, not all bacteria can be definitively classified by this technique. This gives rise to gram-variable and gram-indeterminate groups.

History edit

The method is named after its inventor, the Danish scientist Hans Christian Gram (1853–1938), who developed the technique while working with Carl Friedländer in the morgue of the city hospital in Berlin in 1884. Gram devised his technique not for the purpose of distinguishing one type of bacterium from another but to make bacteria more visible in stained sections of lung tissue.[4] He published his method in 1884, and included in his short report the observation that the typhus bacillus did not retain the stain.[5]

Uses edit

 
Gram stain of Candida albicans from a vaginal swab. The small oval chlamydospores are 2–4 µm in diameter.

Gram staining is a bacteriological laboratory technique[6] used to differentiate bacterial species into two large groups (gram-positive and gram-negative) based on the physical properties of their cell walls.[7][page needed] Gram staining can also be used to diagnose a fungal infection.[1] Gram staining is not used to classify archaea, since these microorganisms yield widely varying responses that do not follow their phylogenetic groups.[8]

Some organisms are gram-variable (meaning they may stain either negative or positive); some are not stained with either dye used in the Gram technique and are not seen.

Medical edit

 
Example of a workup algorithm of possible bacterial infection in cases with no specifically requested targets (non-bacteria, mycobacteria etc.), with most common situations and agents seen in a New England community hospital setting. In this setting, Gram stain is used even before agar plate cultures for blood and cerebrospinal fluid specimens. Furthermore, for cases having undergone culture, Gram stain is shown as a major determinant for further workup.
See also: Pathogenic bacteria

Gram stains are performed on body fluid or biopsy when infection is suspected. Gram stains yield results much more quickly than culturing, and are especially important when infection would make an important difference in the patient's treatment and prognosis; examples are cerebrospinal fluid for meningitis and synovial fluid for septic arthritis.[9][10]

Staining mechanism edit

 
Purple-stained gram-positive (left) and pink-stained gram-negative (right)

Gram-positive bacteria have a thick mesh-like cell wall made of peptidoglycan (50–90% of cell envelope), and as a result are stained purple by crystal violet, whereas gram-negative bacteria have a thinner layer (10% of cell envelope), so do not retain the purple stain and are counter-stained pink by safranin. There are four basic steps of the Gram stain:

  1. Applying a primary stain (crystal violet) to a heat-fixed smear of a bacterial culture. Heat fixation kills some bacteria but is mostly used to affix the bacteria to the slide so that they do not rinse out during the staining procedure.
  2. The addition of iodine, which binds to crystal violet and traps it in the cell
  3. Rapid decolorization with ethanol or acetone
  4. Counterstaining with safranin.[11] Carbol fuchsin is sometimes substituted for safranin since it more intensely stains anaerobic bacteria, but it is less commonly used as a counterstain.[12]
Summary of Gram stain
Application of Reagent Cell color
Gram-positive Gram-negative
Primary dye crystal violet purple purple
mordant iodine purple purple
Decolorizer alcohol/acetone purple colorless
Counter stain safranin/carbol fuchsin purple pink or red

Crystal violet (CV) dissociates in aqueous solutions into CV+
 and chloride (Cl
) ions. These ions penetrate the cell wall of both gram-positive and gram-negative cells. The CV+
 ion interacts with negatively charged components of bacterial cells and stains the cells purple.[13]

Iodide (I
 or I
3) interacts with CV+
 and forms large complexes of crystal violet and iodine (CV–I) within the inner and outer layers of the cell. Iodine is often referred to as a mordant, but is a trapping agent that prevents the removal of the CV–I complex and, therefore, colors the cell.[14]

When a decolorizer such as alcohol or acetone is added, it interacts with the lipids of the cell membrane.[15] A gram-negative cell loses its outer lipopolysaccharide membrane, and the inner peptidoglycan layer is left exposed. The CV–I complexes are washed from the gram-negative cell along with the outer membrane.[16] In contrast, a gram-positive cell becomes dehydrated from an ethanol treatment. The large CV–I complexes become trapped within the gram-positive cell due to the multilayered nature of its peptidoglycan.[16] The decolorization step is critical and must be timed correctly; the crystal violet stain is removed from both gram-positive and negative cells if the decolorizing agent is left on too long (a matter of seconds).[17]

After decolorization, the gram-positive cell remains purple and the gram-negative cell loses its purple color.[17] Counterstain, which is usually positively charged safranin or basic fuchsine, is applied last to give decolorized gram-negative bacteria a pink or red color.[3][18] Both gram-positive bacteria and gram-negative bacteria pick up the counterstain. The counterstain, however, is unseen on gram-positive bacteria because of the darker crystal violet stain.

Examples edit

Gram-positive bacteria edit

 
Gram-stain of gram-positive streptococci surrounded by pus cells
Main article: Gram-positive bacteria

Gram-positive bacteria generally have a single membrane (monoderm) surrounded by a thick peptidoglycan. This rule is followed by two phyla: Bacillota (except for the classes Mollicutes and Negativicutes) and the Actinomycetota.[7][19] In contrast, members of the Chloroflexota (green non-sulfur bacteria) are monoderms but possess a thin or absent (class Dehalococcoidetes) peptidoglycan and can stain negative, positive or indeterminate; members of the Deinococcota stain positive but are diderms with a thick peptidoglycan.[7][page needed][19]

Historically, the gram-positive forms made up the phylum Firmicutes, a name now used for the largest group. It includes many well-known genera such as Lactobacillus, Bacillus, Listeria, Staphylococcus, Streptococcus, Enterococcus, and Clostridium.[20] It has also been expanded to include the Mollicutes, bacteria such as Mycoplasma and Thermoplasma that lack cell walls and so cannot be Gram-stained, but are derived from such forms.[21]

Some bacteria have cell walls which are particularly adept at retaining stains. These will appear positive by Gram stain even though they are not closely related to other gram-positive bacteria. These are called acid-fast bacteria, and can only be differentiated from other gram-positive bacteria by special staining procedures.[22]

Gram-negative bacteria edit

Main article: Gram-negative bacteria
 
Gram negative Neisseria gonorrhoeae and pus cells

Gram-negative bacteria generally possess a thin layer of peptidoglycan between two membranes (diderm).[23] Lipopolysaccharide (LPS) is the most abundant antigen on the cell surface of most gram-negative bacteria, contributing up to 80% of the outer membrane of E. coli and Salmonella.[24] Most bacterial phyla are gram-negative, including the cyanobacteria, green sulfur bacteria, and most Pseudomonadota (exceptions being some members of the Rickettsiales and the insect-endosymbionts of the Enterobacteriales).[7][page needed][19]

Gram-variable and gram-indeterminate bacteria edit

Some bacteria, after staining with the Gram stain, yield a gram-variable pattern: a mix of pink and purple cells are seen.[16][25] In cultures of Bacillus, Butyrivibrio, and Clostridium, a decrease in peptidoglycan thickness during growth coincides with an increase in the number of cells that stain gram-negative.[25] In addition, in all bacteria stained using the Gram stain, the age of the culture may influence the results of the stain.[25]

Gram-indeterminate bacteria do not respond predictably to Gram staining and, therefore, cannot be determined as either gram-positive or gram-negative. Examples include many species of Mycobacterium, including Mycobacterium bovis, Mycobacterium leprae and Mycobacterium tuberculosis, the latter two of which are the causative agents of leprosy and tuberculosis, respectively.[26][27] Bacteria of the genus Mycoplasma lack a cell wall around their cell membranes,[9] which means they do not stain by Gram's method and are resistant to the antibiotics that target cell wall synthesis.[28][29]

Orthographic note edit

The term Gram staining is derived from the surname of Hans Christian Gram; the eponym (Gram) is therefore capitalized but not the common noun (stain) as is usual for scientific terms.[30] The initial letters of gram-positive and gram-negative, which are eponymous adjectives, can be either capital G or lowercase g, depending on what style guide (if any) governs the document being written. Lowercase style is used by the US Centers for Disease Control and Prevention and other style regimens such as the AMA style.[31] Dictionaries may use lowercase,[32][33] uppercase,[34][35][36][37] or both.[38][39] Uppercase Gram-positive or Gram-negative usage is also common in many scientific journal articles and publications.[39][40][41] When articles are submitted to journals, each journal may or may not apply house style to the postprint version. Preprint versions contain whichever style the author happened to use. Even style regimens that use lowercase for the adjectives gram-positive and gram-negative still typically use capital for Gram stain.

See also edit

References edit

  1. ^ a b "Gram Stain: MedlinePlus Medical Test". medlineplus.gov.
  2. ^ Colco, R. (2005). "Gram Staining". Current Protocols in Microbiology. Appendix 3 (1): Appendix 3C. doi:10.1002/9780471729259.mca03cs00. ISBN 978-0471729259. PMID 18770544. S2CID 32452815.
  3. ^ a b Beveridge, T. J.; Davies, J. A. (November 1983). "Cellular responses of Bacillus subtilis and Escherichia coli to the Gram stain". Journal of Bacteriology. 156 (2): 846–58. doi:10.1128/JB.156.2.846-858.1983. PMC 217903. PMID 6195148.
  4. ^ Austrian, R. (1960). "The Gram stain and the etiology of lobar pneumonia, an historical note". Bacteriological Reviews. 24 (3): 261–265. doi:10.1128/MMBR.24.3.261-265.1960. PMC 441053. PMID 13685217.
  5. ^ Gram, Hans Christian (1884). "Über die isolierte Färbung der Schizomyceten in Schnitt- und Trockenpräparaten". Fortschritte der Medizin (in German). 2: 185–189..
    English translation in: Brock, T. D. (1999). Milestones in Microbiology 1546–1940 (2nd ed.). ASM Press. pp. 215–218. ISBN 978-1-55581-142-6.
    Translation is also at: Brock, T. D. "Pioneers in Medical Laboratory Science: Christian Gram 1884". HOSLink.com. Retrieved 27 July 2010.
  6. ^ Ryan, K. J.; Ray, C. G., eds. (2004). Sherris Medical Microbiology (4th ed.). McGraw Hill. pp. 232f. ISBN 978-0838585290.
  7. ^ a b c d Madigan, M. T.; Martinko, J.; Parker, J. (2004). Brock Biology of Microorganisms (10th ed.). Lippincott Williams & Wilkins. ISBN 978-0-13-066271-2.
  8. ^ Beveridge, T. J. (2001). "Use of the Gram stain in microbiology". Biotechnic & Histochemistry. 76 (3): 111–118. doi:10.1080/714028139. PMID 11475313.
  9. ^ a b Ryan KJ, Ray CG (editors) (2004). Sherris Medical Microbiology (4th ed.). McGraw Hill. pp. 409–12. ISBN 978-0-8385-8529-0. {{cite book}}: |author= has generic name (help)
  10. ^ Søgaard, M.; Nørgaard, M.; Schønheyder, H. (2007). "First notification of positive blood cultures: High accuracy of the Gram stain report". Journal of Clinical Microbiology. 45 (4): 1113–1117. doi:10.1128/JCM.02523-06. PMC 1865800. PMID 17301283.
  11. ^ Black, Jacquelyn G. (1993). Microbiology: Principles and Explorations. Prentice Hall. p. 65.
  12. ^ "Medical Chemical Corporation". Med-Chem.com. Retrieved 9 March 2016.
  13. ^ Leboffe, Michael (2014). Microbiology Laboratory Theory and Application (3rd ed.). Englewood, Colorado: Morton Publishing Company. p. 105. ISBN 978-1617312809.
  14. ^ . StainsFile.info. Archived from the original on 9 March 2016. Retrieved 9 March 2016.
  15. ^ "Gram Stain". Microbugz. Austin Community College. Retrieved 2017-05-26.
  16. ^ a b c Tim, Sandle (21 October 2015). Pharmaceutical Microbiology: Essentials for Quality Assurance and Quality Control. Elsevier Science. ISBN 9780081000229. OCLC 923807961.
  17. ^ a b Hardy, Jay; Maria, Santa. "Gram's Serendipitous Stain" (PDF). Hardy's Diagnostics. (PDF) from the original on 2017-03-24.
  18. ^ Davies, J. A.; Anderson, G. K.; Beveridge, T. J.; Clark, H. C. (November 1983). "Chemical mechanism of the Gram stain and synthesis of a new electron-opaque marker for electron microscopy, which replaces the iodine mordant of the stain". Journal of Bacteriology. 156 (2): 837–845. doi:10.1128/JB.156.2.837-845.1983. PMC 217902. PMID 6195147.
  19. ^ a b c Brenner, Don J.; Krieg, Noel R.; Staley, James T. (26 July 2005) [1984]. Garrity, George M. (ed.). Introductory Essays. Bergey's Manual of Systematic Bacteriology. Vol. 2A (2nd ed.). New York: Springer. p. 304. ISBN 978-0-387-24143-2. British Library no. GBA561951.
  20. ^ Galperin, Michael Y. (27 December 2013). "Genome Diversity of Spore-forming Firmicutes". Microbiology Spectrum. 1 (2): TBS-0015-2012-. doi:10.1128/microbiolspectrum.tbs-0015-2012. ISSN 2165-0497. PMC 4306282. PMID 26184964.
  21. ^ Hashem, Hams H. "Practical Medical Microbiology". University of Al-Qadisiya.
  22. ^ . www2.Highlands.edu. Georgia Highlands College. Archived from the original on 10 June 2017. Retrieved 10 June 2017.
  23. ^ Megrian D, Taib N, Witwinowski J, Gribaldo S (2020). "One or two membranes? Diderm Firmicutes challenge the Gram-positive/Gram-negative divide". Molecular Microbiology. 113 (3): 659–671. doi:10.1111/mmi.14469. PMID 31975449. S2CID 210882600.
  24. ^ Avila-Calderón ED, Ruiz-Palma MD, Contreras-Rodríguez A (2021). "Outer Membrane Vesicles of Gram-Negative Bacteria: An Outlook on Biogenesis". Frontiers in Microbiology. 12: 557902. doi:10.3389/fmicb.2021.557902. PMC 7969528. PMID 33746909.
  25. ^ a b c Beveridge, Terry J. (March 1990). "Mechanism of Gram Variability in Select Bacteria". Journal of Bacteriology. 172 (3): 1609–1620. doi:10.1128/jb.172.3.1609-1620.1990. PMC 208639. PMID 1689718.
  26. ^ Black, Jacquelyn (2012). Microbiology: Principles and Exploration (8th ed.). John Wiley & Sons. p. 68. ISBN 978-0-470-54109-8.
  27. ^ Reynolds, J.; Moyes, R. B.; Breakwell, D. P. (2009). "Appendix 3". Differential staining of bacteria: Acid fast stain. Vol. Appendix 3. pp. H. doi:10.1002/9780471729259.mca03hs15. ISBN 978-0471729259. PMID 19885935. S2CID 45685776. {{cite book}}: |journal= ignored (help)
  28. ^ Lee EH, Winter HL, van Dijl JM, Metzemaekers JD, Arends JP (December 2012). "Diagnosis and antimicrobial therapy of Mycoplasma hominis meningitis in adults". International Journal of Medical Microbiology. 302 (7–8): 289–92. doi:10.1016/j.ijmm.2012.09.003. PMID 23085510.
  29. ^ Gautier-Bouchardon AV (July 2018). "Antimicrobial Resistance in Mycoplasma spp". Microbiology Spectrum. 6 (4): 425–446. doi:10.1128/microbiolspec.ARBA-0030-2018. ISBN 9781555819798. PMID 30003864. S2CID 51616821.
  30. ^ Waddingham, Anne (28 August 2014). New Hart's Rules: The Oxford Style Guide. Oxford University Press. p. 105. ISBN 978-0199570027.
  31. ^ "Preferred Usage". Emerging Infectious Diseases Style Guide. Centers for Disease Control and Prevention.
  32. ^ "Dorland's Illustrated Medical Dictionary" (32nd ed.). Elsevier. Retrieved 5 June 2020. Use search terms such as gram-negative.
  33. ^ "gram–positive", Merriam-Webster, Encyclopædia Britannica, Inc.
  34. ^ "Gram-positive". CollinsDictionary.com. HarperCollins.
  35. ^ . Lexico.com. Oxford University Press. Archived from the original on June 5, 2020.
  36. ^ "Gram-positive". MedicineNet.
  37. ^ . BusinessDictionary.com. Archived from the original on 2016-10-20. Retrieved 2016-10-20.
  38. ^ "gram-pos·i·tive or Gram-pos·i·tive". The American Heritage Dictionary. Houghton Mifflin.
  39. ^ a b "Gram-positive". Dictionary.com.
  40. ^ Brown, Lisa; Wolf, Julie M.; Prados-Rosales, Rafael; Casadevall, Arturo (2015). "Through the wall: Extracellular vesicles in Gram-positive bacteria, mycobacteria and fungi". Nature Reviews Microbiology. 13 (10): 620–630. doi:10.1038/nrmicro3480. PMC 4860279. PMID 26324094.
  41. ^ Mueller, Kristen L. (12 June 2015). "Detecting Gram-negative bacteria". Science. 348 (6240): 1218. doi:10.1126/science.348.6240.1218-o.

External links edit

 
Wikimedia Commons has media related to Gram stains.
 
The Wikibook School Science has a page on the topic of: Gram staining
  • Gram staining technique video

February 15, 2024
gram, stain, gram, method, method, staining, used, classify, bacterial, species, into, large, groups, gram, positive, bacteria, gram, negative, bacteria, also, used, diagnose, fungal, infection, name, comes, from, danish, bacteriologist, hans, christian, gram,. Gram stain Gram staining or Gram s method is a method of staining used to classify bacterial species into two large groups gram positive bacteria and gram negative bacteria It may also be used to diagnose a fungal infection 1 The name comes from the Danish bacteriologist Hans Christian Gram who developed the technique in 1884 2 Micrograph of a gram positive coccus and a gram negative rod A Gram stain of mixed Staphylococcus aureus S aureus ATCC 25923 gram positive cocci in purple and Escherichia coli E coli ATCC 11775 gram negative bacilli in red the most common Gram stain reference bacteriaGram staining differentiates bacteria by the chemical and physical properties of their cell walls Gram positive cells have a thick layer of peptidoglycan in the cell wall that retains the primary stain crystal violet Gram negative cells have a thinner peptidoglycan layer that allows the crystal violet to wash out on addition of ethanol They are stained pink or red by the counterstain 3 commonly safranin or fuchsine Lugol s iodine solution is always added after addition of crystal violet to strengthen the bonds of the stain with the cell membrane Gram staining is almost always the first step in the identification of a bacterial group While Gram staining is a valuable diagnostic tool in both clinical and research settings not all bacteria can be definitively classified by this technique This gives rise to gram variable and gram indeterminate groups Contents 1 History 2 Uses 2 1 Medical 3 Staining mechanism 4 Examples 4 1 Gram positive bacteria 4 2 Gram negative bacteria 4 3 Gram variable and gram indeterminate bacteria 5 Orthographic note 6 See also 7 References 8 External linksHistory editThe method is named after its inventor the Danish scientist Hans Christian Gram 1853 1938 who developed the technique while working with Carl Friedlander in the morgue of the city hospital in Berlin in 1884 Gram devised his technique not for the purpose of distinguishing one type of bacterium from another but to make bacteria more visible in stained sections of lung tissue 4 He published his method in 1884 and included in his short report the observation that the typhus bacillus did not retain the stain 5 Uses edit nbsp Gram stain of Candida albicans from a vaginal swab The small oval chlamydospores are 2 4 µm in diameter Gram staining is a bacteriological laboratory technique 6 used to differentiate bacterial species into two large groups gram positive and gram negative based on the physical properties of their cell walls 7 page needed Gram staining can also be used to diagnose a fungal infection 1 Gram staining is not used to classify archaea since these microorganisms yield widely varying responses that do not follow their phylogenetic groups 8 Some organisms are gram variable meaning they may stain either negative or positive some are not stained with either dye used in the Gram technique and are not seen Medical edit nbsp Example of a workup algorithm of possible bacterial infection in cases with no specifically requested targets non bacteria mycobacteria etc with most common situations and agents seen in a New England community hospital setting In this setting Gram stain is used even before agar plate cultures for blood and cerebrospinal fluid specimens Furthermore for cases having undergone culture Gram stain is shown as a major determinant for further workup See also Pathogenic bacteria Gram stains are performed on body fluid or biopsy when infection is suspected Gram stains yield results much more quickly than culturing and are especially important when infection would make an important difference in the patient s treatment and prognosis examples are cerebrospinal fluid for meningitis and synovial fluid for septic arthritis 9 10 Staining mechanism edit nbsp Purple stained gram positive left and pink stained gram negative right Gram positive bacteria have a thick mesh like cell wall made of peptidoglycan 50 90 of cell envelope and as a result are stained purple by crystal violet whereas gram negative bacteria have a thinner layer 10 of cell envelope so do not retain the purple stain and are counter stained pink by safranin There are four basic steps of the Gram stain Applying a primary stain crystal violet to a heat fixed smear of a bacterial culture Heat fixation kills some bacteria but is mostly used to affix the bacteria to the slide so that they do not rinse out during the staining procedure The addition of iodine which binds to crystal violet and traps it in the cell Rapid decolorization with ethanol or acetone Counterstaining with safranin 11 Carbol fuchsin is sometimes substituted for safranin since it more intensely stains anaerobic bacteria but it is less commonly used as a counterstain 12 Summary of Gram stain Application of Reagent Cell colorGram positive Gram negativePrimary dye crystal violet purple purplemordant iodine purple purpleDecolorizer alcohol acetone purple colorlessCounter stain safranin carbol fuchsin purple pink or redCrystal violet CV dissociates in aqueous solutions into CV and chloride Cl ions These ions penetrate the cell wall of both gram positive and gram negative cells The CV ion interacts with negatively charged components of bacterial cells and stains the cells purple 13 Iodide I or I 3 interacts with CV and forms large complexes of crystal violet and iodine CV I within the inner and outer layers of the cell Iodine is often referred to as a mordant but is a trapping agent that prevents the removal of the CV I complex and therefore colors the cell 14 When a decolorizer such as alcohol or acetone is added it interacts with the lipids of the cell membrane 15 A gram negative cell loses its outer lipopolysaccharide membrane and the inner peptidoglycan layer is left exposed The CV I complexes are washed from the gram negative cell along with the outer membrane 16 In contrast a gram positive cell becomes dehydrated from an ethanol treatment The large CV I complexes become trapped within the gram positive cell due to the multilayered nature of its peptidoglycan 16 The decolorization step is critical and must be timed correctly the crystal violet stain is removed from both gram positive and negative cells if the decolorizing agent is left on too long a matter of seconds 17 After decolorization the gram positive cell remains purple and the gram negative cell loses its purple color 17 Counterstain which is usually positively charged safranin or basic fuchsine is applied last to give decolorized gram negative bacteria a pink or red color 3 18 Both gram positive bacteria and gram negative bacteria pick up the counterstain The counterstain however is unseen on gram positive bacteria because of the darker crystal violet stain Examples editGram positive bacteria edit nbsp Gram stain of gram positive streptococci surrounded by pus cellsMain article Gram positive bacteria Gram positive bacteria generally have a single membrane monoderm surrounded by a thick peptidoglycan This rule is followed by two phyla Bacillota except for the classes Mollicutes and Negativicutes and the Actinomycetota 7 19 In contrast members of the Chloroflexota green non sulfur bacteria are monoderms but possess a thin or absent class Dehalococcoidetes peptidoglycan and can stain negative positive or indeterminate members of the Deinococcota stain positive but are diderms with a thick peptidoglycan 7 page needed 19 Historically the gram positive forms made up the phylum Firmicutes a name now used for the largest group It includes many well known genera such as Lactobacillus Bacillus Listeria Staphylococcus Streptococcus Enterococcus and Clostridium 20 It has also been expanded to include the Mollicutes bacteria such as Mycoplasma and Thermoplasma that lack cell walls and so cannot be Gram stained but are derived from such forms 21 Some bacteria have cell walls which are particularly adept at retaining stains These will appear positive by Gram stain even though they are not closely related to other gram positive bacteria These are called acid fast bacteria and can only be differentiated from other gram positive bacteria by special staining procedures 22 Gram negative bacteria edit Main article Gram negative bacteria nbsp Gram negative Neisseria gonorrhoeae and pus cellsGram negative bacteria generally possess a thin layer of peptidoglycan between two membranes diderm 23 Lipopolysaccharide LPS is the most abundant antigen on the cell surface of most gram negative bacteria contributing up to 80 of the outer membrane of E coli and Salmonella 24 Most bacterial phyla are gram negative including the cyanobacteria green sulfur bacteria and most Pseudomonadota exceptions being some members of the Rickettsiales and the insect endosymbionts of the Enterobacteriales 7 page needed 19 Gram variable and gram indeterminate bacteria edit Some bacteria after staining with the Gram stain yield a gram variable pattern a mix of pink and purple cells are seen 16 25 In cultures of Bacillus Butyrivibrio and Clostridium a decrease in peptidoglycan thickness during growth coincides with an increase in the number of cells that stain gram negative 25 In addition in all bacteria stained using the Gram stain the age of the culture may influence the results of the stain 25 Gram indeterminate bacteria do not respond predictably to Gram staining and therefore cannot be determined as either gram positive or gram negative Examples include many species of Mycobacterium including Mycobacterium bovis Mycobacterium leprae and Mycobacterium tuberculosis the latter two of which are the causative agents of leprosy and tuberculosis respectively 26 27 Bacteria of the genus Mycoplasma lack a cell wall around their cell membranes 9 which means they do not stain by Gram s method and are resistant to the antibiotics that target cell wall synthesis 28 29 Orthographic note editThe term Gram staining is derived from the surname of Hans Christian Gram the eponym Gram is therefore capitalized but not the common noun stain as is usual for scientific terms 30 The initial letters of gram positive and gram negative which are eponymous adjectives can be either capital G or lowercase g depending on what style guide if any governs the document being written Lowercase style is used by the US Centers for Disease Control and Prevention and other style regimens such as the AMA style 31 Dictionaries may use lowercase 32 33 uppercase 34 35 36 37 or both 38 39 Uppercase Gram positive or Gram negative usage is also common in many scientific journal articles and publications 39 40 41 When articles are submitted to journals each journal may or may not apply house style to the postprint version Preprint versions contain whichever style the author happened to use Even style regimens that use lowercase for the adjectives gram positive and gram negative still typically use capital for Gram stain See also editBacterial cell structure Ziehl Neelsen stainReferences edit a b Gram Stain MedlinePlus Medical Test medlineplus gov Colco R 2005 Gram Staining Current Protocols in Microbiology Appendix 3 1 Appendix 3C doi 10 1002 9780471729259 mca03cs00 ISBN 978 0471729259 PMID 18770544 S2CID 32452815 a b Beveridge T J Davies J A November 1983 Cellular responses of Bacillus subtilis and Escherichia coli to the Gram stain Journal of Bacteriology 156 2 846 58 doi 10 1128 JB 156 2 846 858 1983 PMC 217903 PMID 6195148 Austrian R 1960 The Gram stain and the etiology of lobar pneumonia an historical note Bacteriological Reviews 24 3 261 265 doi 10 1128 MMBR 24 3 261 265 1960 PMC 441053 PMID 13685217 Gram Hans Christian 1884 Uber die isolierte Farbung der Schizomyceten in Schnitt und Trockenpraparaten Fortschritte der Medizin in German 2 185 189 English translation in Brock T D 1999 Milestones in Microbiology 1546 1940 2nd ed ASM Press pp 215 218 ISBN 978 1 55581 142 6 Translation is also at Brock T D Pioneers in Medical Laboratory Science Christian Gram 1884 HOSLink com Retrieved 27 July 2010 Ryan K J Ray C G eds 2004 Sherris Medical Microbiology 4th ed McGraw Hill pp 232f ISBN 978 0838585290 a b c d Madigan M T Martinko J Parker J 2004 Brock Biology of Microorganisms 10th ed Lippincott Williams amp Wilkins ISBN 978 0 13 066271 2 Beveridge T J 2001 Use of the Gram stain in microbiology Biotechnic amp Histochemistry 76 3 111 118 doi 10 1080 714028139 PMID 11475313 a b Ryan KJ Ray CG editors 2004 Sherris Medical Microbiology 4th ed McGraw Hill pp 409 12 ISBN 978 0 8385 8529 0 a href Template Cite book html title Template Cite book cite book a author has generic name help Sogaard M Norgaard M Schonheyder H 2007 First notification of positive blood cultures High accuracy of the Gram stain report Journal of Clinical Microbiology 45 4 1113 1117 doi 10 1128 JCM 02523 06 PMC 1865800 PMID 17301283 Black Jacquelyn G 1993 Microbiology Principles and Explorations Prentice Hall p 65 Medical Chemical Corporation Med Chem com Retrieved 9 March 2016 Leboffe Michael 2014 Microbiology Laboratory Theory and Application 3rd ed Englewood Colorado Morton Publishing Company p 105 ISBN 978 1617312809 Stain theory What a mordant is not StainsFile info Archived from the original on 9 March 2016 Retrieved 9 March 2016 Gram Stain Microbugz Austin Community College Retrieved 2017 05 26 a b c Tim Sandle 21 October 2015 Pharmaceutical Microbiology Essentials for Quality Assurance and Quality Control Elsevier Science ISBN 9780081000229 OCLC 923807961 a b Hardy Jay Maria Santa Gram s Serendipitous Stain PDF Hardy s Diagnostics Archived PDF from the original on 2017 03 24 Davies J A Anderson G K Beveridge T J Clark H C November 1983 Chemical mechanism of the Gram stain and synthesis of a new electron opaque marker for electron microscopy which replaces the iodine mordant of the stain Journal of Bacteriology 156 2 837 845 doi 10 1128 JB 156 2 837 845 1983 PMC 217902 PMID 6195147 a b c Brenner Don J Krieg Noel R Staley James T 26 July 2005 1984 Garrity George M ed Introductory Essays Bergey s Manual of Systematic Bacteriology Vol 2A 2nd ed New York Springer p 304 ISBN 978 0 387 24143 2 British Library no GBA561951 Galperin Michael Y 27 December 2013 Genome Diversity of Spore forming Firmicutes Microbiology Spectrum 1 2 TBS 0015 2012 doi 10 1128 microbiolspectrum tbs 0015 2012 ISSN 2165 0497 PMC 4306282 PMID 26184964 Hashem Hams H Practical Medical Microbiology University of Al Qadisiya The Acid Fast Stain www2 Highlands edu Georgia Highlands College Archived from the original on 10 June 2017 Retrieved 10 June 2017 Megrian D Taib N Witwinowski J Gribaldo S 2020 One or two membranes Diderm Firmicutes challenge the Gram positive Gram negative divide Molecular Microbiology 113 3 659 671 doi 10 1111 mmi 14469 PMID 31975449 S2CID 210882600 Avila Calderon ED Ruiz Palma MD Contreras Rodriguez A 2021 Outer Membrane Vesicles of Gram Negative Bacteria An Outlook on Biogenesis Frontiers in Microbiology 12 557902 doi 10 3389 fmicb 2021 557902 PMC 7969528 PMID 33746909 a b c Beveridge Terry J March 1990 Mechanism of Gram Variability in Select Bacteria Journal of Bacteriology 172 3 1609 1620 doi 10 1128 jb 172 3 1609 1620 1990 PMC 208639 PMID 1689718 Black Jacquelyn 2012 Microbiology Principles and Exploration 8th ed John Wiley amp Sons p 68 ISBN 978 0 470 54109 8 Reynolds J Moyes R B Breakwell D P 2009 Appendix 3 Differential staining of bacteria Acid fast stain Vol Appendix 3 pp H doi 10 1002 9780471729259 mca03hs15 ISBN 978 0471729259 PMID 19885935 S2CID 45685776 a href Template Cite book html title Template Cite book cite book a journal ignored help Lee EH Winter HL van Dijl JM Metzemaekers JD Arends JP December 2012 Diagnosis and antimicrobial therapy of Mycoplasma hominis meningitis in adults International Journal of Medical Microbiology 302 7 8 289 92 doi 10 1016 j ijmm 2012 09 003 PMID 23085510 Gautier Bouchardon AV July 2018 Antimicrobial Resistance in Mycoplasma spp Microbiology Spectrum 6 4 425 446 doi 10 1128 microbiolspec ARBA 0030 2018 ISBN 9781555819798 PMID 30003864 S2CID 51616821 Waddingham Anne 28 August 2014 New Hart s Rules The Oxford Style Guide Oxford University Press p 105 ISBN 978 0199570027 Preferred Usage Emerging Infectious Diseases Style Guide Centers for Disease Control and Prevention Dorland s Illustrated Medical Dictionary 32nd ed Elsevier Retrieved 5 June 2020 Use search terms such as gram negative gram positive Merriam Webster Encyclopaedia Britannica Inc Gram positive CollinsDictionary com HarperCollins Gram stain Lexico com Oxford University Press Archived from the original on June 5 2020 Gram positive MedicineNet Gram negative positive BusinessDictionary com Archived from the original on 2016 10 20 Retrieved 2016 10 20 gram pos i tive or Gram pos i tive The American Heritage Dictionary Houghton Mifflin a b Gram positive Dictionary com Brown Lisa Wolf Julie M Prados Rosales Rafael Casadevall Arturo 2015 Through the wall Extracellular vesicles in Gram positive bacteria mycobacteria and fungi Nature Reviews Microbiology 13 10 620 630 doi 10 1038 nrmicro3480 PMC 4860279 PMID 26324094 Mueller Kristen L 12 June 2015 Detecting Gram negative bacteria Science 348 6240 1218 doi 10 1126 science 348 6240 1218 o External links edit nbsp Wikimedia Commons has media related to Gram stains nbsp The Wikibook School Science has a page on the topic of Gram staining Gram staining technique video Retrieved from https en wikipedia org w index php title Gram stain amp oldid 1203784288, wikipedia, wiki, book, books, library,

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