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Kingella kingae

From Wikipedia, the free encyclopedia

Kingella kingae
Scientific classification Edit this classification
Domain: Bacteria
Phylum: Pseudomonadota
Class: Betaproteobacteria
Order: Neisseriales
Family: Neisseriaceae
Genus: Kingella
Species:
K. kingae
Binomial name
Kingella kingae
(Henriksen and Bøvre 1968) Henriksen and Bøvre 1976

Kingella kingae is a species of Gram-negative facultative anaerobic β-hemolytic coccobacilli. First isolated in 1960 by Elizabeth O. King, it was not recognized as a significant cause of infection in young children until the 1990s, when culture techniques had improved enough for it to be recognized. It is best known as a cause of septic arthritis, osteomyelitis, spondylodiscitis, bacteraemia, and endocarditis, and less frequently lower respiratory tract infections and meningitis.[1]

There are four species of Kingella: K. kingae, the most common, is part of the bacterial flora of the throat in young children and is transmitted from child to child. When it causes disease, the clinical presentation is often subtle and preceded by a recent history of stomatitis or upper respiratory infection. Other species are K. indologenes, K. denitrificans (both causing endocarditis) and K. oralis found in dental plaque.

One notable exception is in cases of endocarditis (heart valve infection), which can be more refractory to treatment. K. kingae is the fifth member of the HACEK group of fastidious Gram-negative bacteria that cause endocarditis. Routine laboratory tests may be normal because the organism is difficult to culture. Inoculating the fluid from infected joints directly into blood culture vials can enhance the chances of an accurate culture, but extended culture times are not helpful.[2]

The organism has also been known as Moraxella kingae.

Kingella kingae is oxidase-positive, catalase-negative, and beta-hemolytic.

Mechanism of infection

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Kingella kingae is thought to begin infection by colonizing the pharynx, crossing the epithelium by using an RTX toxin, and entering the circulation and reaching deeper tissues, such as bones and joints.

Kingella kingae expresses type IV pili, which allow for enhanced adhesion to respiratory epithelial and synovial cells and thus increased likelihood of colonization. These pili have also been shown to be reduced in number as pathogenesis progresses. σ54 regulates the transcription of pilA1, a major pilus subunit. PilS and PilR, regulatory transcription factors best known from the Pseudomonas aeruginosa pilus system, also may regulate pilA expression. High levels of type IV pili on K. kingae are associated with spreading/corroding colony types, while low levels of type IV pili are associated with nonspreading/noncorroding colony types of K. kingae.[3] The three different types of populations are: spreading/corroding (with high-density piliation), nonspreading/noncorroding colonies (low density piliation), and domed colonies (no piliation, and thus no adherence to epithelium). Generally, respiratory and nonendocarditis infections tend to be highly piliated, while joint fluid, bone, and endocarditis blood isolates are less piliated, if at all.[4]

Spondylodiscitis

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Children under three years of age may become infected with K. kingae and develop spondylodiscitis. Typical symptoms include back pain, abdominal pain, and damage to the bones and joints. It generally targets the lumbar region of the spinal cord, and the only true way of diagnosing it is through biopsy or needle aspiration, as blood plate growth gives many false negatives.[5]

Osteomyelitis

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Osteomyelitis occurs in previously healthy children. The infection rate is poorly documented, thus the illness tends to go underdiagnosed. K. kingae can be transmitted person to person in rare cases. Diagnostic tools include low-grade fever, elevated inflammatory markers (ESR and CRP), but white blood cell counts are generally unreliable since they vary among infected patients. K. kingae infections are generally concomitant with upper respiratory diseases or stomatitis, since disrupted respiratory or buccal mucosa is likely to facilitate bacterial invasion and hematogenous dissemination.

The cause of osteoarticular infections is frequently not identified. Less than 15% of K. kingae-positive clinical specimens reveal organisms on Gram stain. [6] Infections due to K. kingae are treatable with a wide variety of antibiotics, such as beta-lactams, tetracyclines, erythromycin, and fluoroquinolones.[2] Minimum inhibitory concentrations of penicillins, rifampicin, and azithromycin are easily achieved. Multiple studies have shown that inoculating synovial fluid or bone samples directly into blood culture bottles substantially increases the detection of K. kingae compared with direct plating of specimens on solid media.

As an oropharyngeal colonizer, K. kingae is transmitted by respiratory secretions, saliva, and potentially oral contact with contaminated objects. Recent studies suggest K. kingae strains may demonstrate varying degrees of pathogenicity, which could support the person-to-person transfer of pathogenic K. kingae. Infection has been shown to have high prevalence in the autumn and winter months.[6]

Infections in adults

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K.kingae infections are rare in adults, but they occur in immunocompromised patients. Poor oral hygiene, pharyngitis, and mucosal ulceration are also predisposing factors for infection. The infection can occur in the respiratory or urinary tracts, as it is a part of the normal flora in those two areas, and will develop into sepsis or septic arthritis.[7] Most K. kingae are sensitive to beta-lactam antibiotics, but reports describe strains producing beta-lactamases.[8] Options include aminoglycosides, macrolides and fluoroquinolones. K. kingae can also cause infectious endocarditis, in children as well as in adults.[9]

References

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  1. ^ Yagupsky P (2004). "Kingella kingae: from medical rarity to an emerging paediatric pathogen". Lancet Infect Dis. 4 (6): 358–67. doi:10.1016/S1473-3099(04)01046-1. PMID 15172344.
  2. ^ a b Petti CA, Bhally HS, Weinstein MP, Joho K, Wakefield T, Reller LB, Carroll KC (2006). "Utility of extended blood culture incubation for isolation of Haemophilus, Actinobacillus, Cardiobacterium, Eikenella, and Kingella organisms: a retrospective multicenter evaluation". J. Clin. Microbiol. 44 (1): 257–9. doi:10.1128/JCM.44.1.257-259.2006. PMC 1351967. PMID 16390985.
  3. ^ Kehl-Fie TE, Porsch EA, Miller SE, St Geme JW (2009). "Expression of Kingella kingae type IV pili is regulated by sigma54, PilS, and PilR". J. Bacteriol. 191 (15): 4976–86. doi:10.1128/JB.00123-09. PMC 2715724. PMID 19465661.
  4. ^ Kehl-Fie TE, Porsch EA, Yagupsky P, Grass EA, Obert C, Benjamin DK, St Geme JW (2010). "Examination of type IV pilus expression and pilus-associated phenotypes in Kingella kingae clinical isolates". Infect. Immun. 78 (4): 1692–9. doi:10.1128/IAI.00908-09. PMC 2849430. PMID 20145101.
  5. ^ Ceroni D, Cherkaoui A, Kaelin A, Schrenzel J (2010). "Kingella kingae spondylodiscitis in young children: toward a new approach for bacteriological investigations? A preliminary report". J Child Orthop. 4 (2): 173–5. doi:10.1007/s11832-009-0233-2. PMC 2839857. PMID 21455474.
  6. ^ a b Kiang KM, Ogunmodede F, Juni BA, Boxrud DJ, Glennen A, Bartkus JM, Cebelinski EA, Harriman K, Koop S, Faville R, Danila R, Lynfield R (2005). "Outbreak of osteomyelitis/septic arthritis caused by Kingella kingae among child care center attendees". Pediatrics. 116 (2): e206–13. doi:10.1542/peds.2004-2051. PMID 16024681.
  7. ^ Ramana K, Mohanty S (2009). "An adult case of urinary tract infection with Kingella kingae: a case report". J Med Case Rep. 3: 7236. doi:10.1186/1752-1947-3-7236. PMC 2726550. PMID 19830146.
  8. ^ Banerjee A, Kaplan JB, Soherwardy A, Nudell Y, Mackenzie GA, Johnson S, Balashova NV (2013). "Characterization of TEM-1 β-lactamase producing Kingella kingae clinical isolates". Antimicrob. Agents Chemother. 57 (9): 4300–4306. doi:10.1128/AAC.00318-13. PMC 3754283. PMID 23796935.
  9. ^ Debora Pierce, Bethany C. Calkins, Kirsten Thornton, Infectious Endocarditis: Diagnosis and Treatment, Am Fam Physician, 2012, 15;85(10):981-986
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