2. Taxonomy
Family vibrionaceae now presently composed of 6 genera.
Vibrio, Photobacterium , Salinivibrio, Enterovibrio, Grimontia and
Aliivibrio.
Pathogenic species for humans were found in 3 genera , including Vibrio (10
species), Photobacterium and Grimontia (one species each).
3. Halophilic Vibrios
Definition: Species of vibrios that are unable to grow in media without added salt
(NaCl) [They require (6-10% NaCl) to grow].
Halophilic means salt loving.
e.g. V.parahaemolyticus, V.alginolyticus, V.vulnificus, V.fluvialis, V. hollisae .
4. Differentiation of halophilic vibrio from non-halophilic vibrios
1. Growth on Cystine Lactose Electrolyte Deficient (CLED) medium (pH 7.5):
Non-halophilic vibrios grow on this medium but halophilic vibrios don‟t grow.
2. Growth in peptone water with different concentrations of NaCl:
A loopful of bacterial suspension is inoculated into a series of peptone water with
NaCl concentration of 0%, 0.5%, 3%, 6%, 8% and 10%.
Halophilic vibrios don‟t grow at 0% NaCl concentration, but show increasing
growth from 0.5% to 3% or more. Non-halophilic vibrios don‟t grow in NaCl
concentration at or beyond 6%.
5. Vibrio parahaemolyticus
Vibrio parahaemolyticus is a gram-negative halophilic bacterium that is indigenous
to coastal marine and estuaries (where rivers flow into the sea) throughout the
world (1).
It is a common cause of acute gastroenteritis characterized by diarrhea, vomiting
and abdominal cramps and the source of some cases of septicemia(2).
It also causes traveller's diarrhea, wound infection, ear infection and secondary
septicemia in humans (Pavia et. al., 1989).
Typically, human infections with this organism result from the consumption of raw
or undercooked seafood especially with molluscan shellfish, such as clams,
oysters, mussels, and scallops(3).
1.Twedt, R. M. 1989. Vibrio parahaemolyticus, p. 552–554. In M. P. Doyle (ed.), Foodborne bacterial pathogens. Marcel Dekker
Inc., New York, N.Y.
2.Blake PA, Weaver RE, Hollis DG. Diseases of humans (other than cholera) caused by vibrios. Annu Rev Microbiol.
1980;34:341-67. Review.
3.Rippey SR. Infectious diseases associated with molluscan shellfish consumption. Clin Microbiol Rev. 1994 Oct;7(4):419-25.
Review.
7. History
This organism was first identified as a causative agent of food
borne gastroenteritis after a large outbreak (272 illnesses and 20
deaths) associated with consumption of half-dried sardines called
“shirasu”, in Japan in 1951 (Fujino et. al., 1953)(4).
Fujino (1951) reported the discovery of this pathogenic bacterium
at the 25th Annual Meeting of the Japanese Association for
Infectious Diseases in 1951.
4.Fujino T, Okuno Y, Nakada D, et al. On the bacteriological examination of shirasu-food poisoning. Med J Osaka
Univ. 1953;4:299-304.
8. History
In India V. parahaemolyticus was first isolated from a case of gastroenteritis by
Chatterjee et. al. (1970) and about 10% of the cases of gastroenteritis in patients
admitted to the Infectious Disease Hospital in Kolkata are due to V.
parahaemolyticus (Deb et. al., 1975) (5).
The United States Centers for Disease Control and Prevention (CDC) estimates
that of the approximately 7,880 Vibrio illnesses each year in the United States,
approximately 2,800 are estimated to be associated with Vibrio parahaemolyticus
and raw oyster consumption.
5.S Nelapati, K Nelapati, B K Chinnam. Vibrio parahaemolyticus- An emerging foodborne pathogen-A Review.
Vet. World, 2012, Vol.5(1): 48-62.
9. Morphology & Characteristics
In morphology, it resembles the cholera vibrio,except that it is capsulated, shows
bipolar staining and has a tendency to pleomorphism, especially when grown on 3%
salt agar and in old cultures.
Unlike other vibrios, it produces peritrichous flagella when grown on solid media.
Polar flagella are formed in liquid cultures.
It grows only in media containing NaCl. It can tolerate salt concentration up to 8% but
not 10 %. The optimum salt concentration is 2-4 %.
On TCBS agar, the colonies are green with an opaque, raised centre and flat
translucent periphery.
String test is positive.
10. Morphology & Characteristics
It is oxidase, catalase, nitrate, indole and citrate positive.
Glucose, maltose, mannitol, mannose and arabinose are fermented
producing acid only. Lactose, sucrose, salicin, xylose, adonitol, inositol and
sorbitol are not fermented.
It is killed at 60 C in 15 minutes.
It does not grow at 4 C but can survive refrigeration and freezing.
Drying destroys it.
It dies in distilled water or vinegar in a few minutes.
11. Epidemiology
Surveillance for V. parahaemolyticus infection was initiated in January 1994 in Calcutta, India.
A group of strains belonging to serovar O3:K6 and possessing the tdh gene but not the trh gene
appeared suddenly in February 1996 and was shown to be responsible for the high incidence of
V. parahaemolyticus infection since then in Calcutta (6)
A large number of the clinical cases seen in the years after 1996 were associated with a unique
clone of V. parahaemolyticus serotype O3:K6 (7).
It was determined that many of the O3:K6 strains isolated since 1996 contain a filamentous
phage, f237.
f237contains a unique open reading frame, ORF8.
Two other V. parahaemolyticus serotypes that were subsequently isolated, O4:K68 and
O1:KUT.
O4:K68 and O1:KUT also contains the f237 phage and therefore the ORF8 gene (7).
6.Okuda J, Ishibashi M, Hayakawa E, Nishino T, Takeda Y, Mukhopadhyay AK, Garg S, Bhattacharya SK, Nair GB, Nishibuchi M. Emergence of a
unique O3:K6 clone of Vibrio parahaemolyticus in Calcutta, India, and isolation of strains from the same clonal group from Southeast Asian travelers
arriving in Japan. J Clin Microbiol. 1997 Dec;35(12):3150-5.
7.Matsumoto C, Okuda J, Ishibashi M, Iwanaga M, Garg P, Rammamurthy T, Wong HC, Depaola A, Kim YB, Albert MJ, Nishibuchi M. Pandemic
spread of an O3:K6 clone of Vibrio parahaemolyticus and emergence of related strains evidenced by arbitrarily primed PCR and toxRS sequence
analyses. J Clin Microbiol. 2000 Feb;38(2):578-85.
12. Contd
It has been demonstrated that serovars O3:K6, O4:K68, and O1: KUT are closely
related, and molecular biology studies have suggested that O4:K68 and O1:KUT
diverged from O3:K6 by genetic alteration of the O and K antigens. Together,
these serotypes have been designated the pandemic group (8).
It has been suggested that ORF8 could play a role in the increased virulence of
the pandemic group strains.
ORF8 could be a useful genetic marker for identification of these strains (9, 10).
8. Okura, M., R. Osawa, A. Iguchi, E. Arakawa, J. Terjima, and H. Watanabe. 2003. Genotypic analyses of Vibrio parahaemolyticus and
development of a pandemic group-specific multiplex PCR assay. J. Clin. Microbiol. 41:4676– 4682.
9. Myers, M. L., G. Panicker, and A. K. Bej. 2003. PCR detection of a newly emerged pandemic Vibrio parahaemolyticus O3:K6 pathogen in
pure cultures and seeded waters from the Gulf of Mexico. Appl. Environ. Microbiol. 69:2194–2200.
10. Nasu, H., T. Iida, T. Sugahara, Y. Yamaichi, K.-S. Park, K. Yokoyama, K. Makino, H. Shinagawa, and T. Honda. 2000. A filamentous phage
associated with recent pandemic Vibrio parahaemolyticus O3:K6 strains. J. Clin. Microbiol. 38:2156–2161.
13. Incidence & Geographic distribution
V. parahaemolyticus-associated gastroenteritis has been reported from North
America, Central America, Europe, Asia, and Africa.
In Asia, V. parahaemolyticus is an established enteric pathogen in Japan, where
consumption of uncooked seafood is common.
V. parahaemolyticus has been reported to cause about 50–70% of the cases of bacterial
food poisoning in Japan (Miwatani & Takeda, 1976; Obata et al., 2001).
Apart from Japan, various Asian countries, such as Thailand (Echeverria et al., 1983;
Sriratanaban & Reinprayoon, 1982), India (Chatterjee et al., 1978; Bag et al., 1999),
Bangladesh (Hughes et al., 1978; Bhuiyan et al., 2002), Laos (Matsumoto et al., 2000),
Vietnam (Neumann et al., 1972; Van and Tuan, 1974), Tanzania (Mhalu et al., 1982),
Hong Kong (Ho & Wong, 1985), Indonesia (Matsumoto et al., 2000), Philippines (Adkins
et al., 1987), and Kuwait (Matsumoto et al., 2000), have reported the isolation of V.
parahaemolyticus from patients suffering from diarrhea.
14. Incidence & Geographic distribution
V. parahaemolyticus has also been isolated from diarrheal cases in Russia
(Boiko et al., 1994), China (Jiang, 1991;Wu et al., 1998), Korea (Matsumoto et
al., 2000), and Taiwan (Wu et al, 1996; Wong et al., 2000).
In USA, V. parahaemolyticus-mediated outbreak was first identified in 1971
during which 320 people suffered from gastroenteritis in Maryland due to food
poisoning (Dadisman et al.,1972; Molenda et al., 1972).
This
was the first confirmed outbreak of food poisoning due to V.
parahaemolyticus outside Japan which is due to consumption of raw oysters.
15. Pathogenesis
The incubation period of V. parahaemolyticus associated gastroenteritis varies
between 4 and 96 h (Miwatani & Takeda, 1976), the mean incubation period
being 15 h (Centers for Disease Control and Prevention, 1998).
The experimental dosages required for initiation of gastroenteritis range from
2x105 to 3x107 CFU.
Pathogenicity was closely correlated with kanagawa phenomenon(KP+) due to
release of kanagawa hemolysin or the thermostable direct hemolysin ((Takeda,
1983; Nishibuchi et. al., 1989).
Clinical isolates of KP negative V. parahaemolyticus from traveler produced
hemolysin, named TDH-related hemolysin (TRH), which is also an important
virulence factor.
Clinical isolates of V.parahemolyticus may produce either TDH/ TRH encoded
by tdh and trh genes respectively(Nishibuchi and Kapar, 1995).
16. Kanagawa phenomenon
Clinical strains of V. parahaemolyticus were observed to produce hemolysis
on special blood agar medium (Kato et al., 1965).
In 1968, Wagatsuma developed a special medium for measuring the
hemolytic character of V. parahaemolyticus called the Wagatsuma agar.
It is a high-salt (7%) blood agar (defibrinated human or rabbit blood) medium
containing d-mannitol as the carbohydrate source.
Hemolysis observed on Wagatsuma agar medium, referred to as the
Kanagawa phenomenon (KP).
Kanagawa phenomenon (KP) has diagnostic as well as pathogenic
significance for V. parahaemolyticus.
17. Kanagawa phenomenon
KP is known to occur due to the expression of TDH that is more frequently
detected in clinical strains of V. parahaemolyticus.
Only 1–2% of the environmental strains of V. parahaemolyticus express the
hemolytic protein and therefore most non-clinical isolates of V. parahaemolyticus
are KP-negative (Miyamoto et al., 1969).
18. Virulence factors of V.parahemolyticus
1.Thermostable direct hemolysin (TDH):
TDH was the first recognized virulence factor for V. parahaemolyticus and has been
used as an important marker for identifying virulent strains (Okuda et. al., 1997a; Cook
et. al., 2002).
The hemolysin is a homodimer protein with a molecular mass of 46 kDa, each peptide
being composed of 165 amino acids with one disulfide bond near the carboxyl terminus.
(Tsunasawa et al., 1987; Honda & Iida, 1993).
TDH is encoded by the tdh gene located in the chromosome, and all KP-positive V.
parahaemolyticus strains contain two tdh gene copies, tdh1 and tdh2, that are 97%
homologous (Nishibuchi & Kaper, 1990, 11).
Vp-TDH exhibits β- hemolytic activity on Wagatsuma medium, which has been termed
the Kanagawa phenomenon (KP).
Purified Vp-TDH is heat-stable, even at 100º C for 10 min and has hemolytic, cytotoxic,
enterotoxic, mouse lethality and cardiotoxic activities.
11.Honda T, Ni Y, Miwatani T, Adachi T, Kim J. The thermostable direct hemolysin of Vibrio parahaemolyticus is
a pore-forming toxin. Can J Microbiol. 1992 Nov;38(11):1175-80.
19. Thermostable direct hemolysin (TDH)
Vp-TDH damages the erythrocyte membrane by acting as a pore-forming toxin,
with the pores estimated at 2 nm in diameter.
Vp-TDH-induced hemolysis occurs in three sequential steps :
1) binding to the erythrocyte membrane, 2) formation of a transmembrane pore,
and 3) disruption of the cell membrane.
Primary target of TDH is the intestinal epithelial cell.
Raimondi et. al. (1995) demonstrated (using rabbit as animal model) that the TDH
is one of the enterotoxin whose action mediated by intracellular calcium.
TDH increases Cl-secretion in human colonic epithelial cells, through mechanisms
involving cell binding and Ca2 + influx, followed by elevation of [Ca2+]in
association with protein kinase C phosphorylation.
TDH has cardiotoxic and cytotoxic effects (Sakazaki et. al., 1974).
20. Thermostable direct hemolysin- related hemolysin (TRH)
TDH-like hemolysin or named Vp-TRH produced by a KP-negative clinical isolate
of V. parahaemolyticus.
Vp- TRH stimulates fluid secretion in the rabbit ileal loop test.
It has an amino acid sequence that is approximately 67% homologous with Vp-
TDH.
Vp-TRH is heat labile at 60º C for 10 min.
TRH is encoded by the trh gene, two copies (trh1 and trh2) of which are found to
be chromosomally located in the V. parahaemolyticus genome.
The two trh loci share 84% sequence identity (Kishishita et al., 1992).
21. Vp-TDH and Vp-TRH
Both Vp-TDH and Vp-TRH induce chloride secretion in human colonic
epithelial cells (12,13,14).
In cultured human colonic epithelial cells, TRH increases Cl(-) secretion,
followed by elevation of intracellular calcium.
12.Takahashi A, Kenjyo N, Imur K, Myonsun Y, Honda T : Cl-secretion in colonic epithelial cells induced by
the Vibrio parahaemolyticus hemolytic toxin related to thermostable direct hemo-lysin. Infect Immun 68 :
5435-5438, 2000.
13.Park KS, Ono T, Rokuda M, Jang MH, Iida T, Honda T : Cytotoxicity and enterotoxicity of the thermostable
direct hemolysin-deletion mutants of Vibrio parahaemolyticus. Microbiol Immunol 48 : 313-318, 2004.
14.Shimohata T, Takahashi A. Diarrhea induced by infection of Vibrio parahaemolyticus. J Med Invest. 2010
Aug;57(3-4):179-82. Review.
22. Thermo labile haemolysin (TLH)
Another thermo-labile haemolysin (TLH) which is encoded by tlh gene is
considered as a species-specific marker(15).
This gene has been detected in all clinical and environmental V.
parahaemolyticus strains.
15.Bej AK, Patterson DP, Brasher CW, Vickery MCL, Jones DD, Kaysner CA. Detection of total and hemolysinproducing Vibrio parahaemolyticus in shellfish using multiplex PCR amplification of tlh, tdh and trh. J.
Microbiol Methods. 1999;36:215-25.
23. Other putative virulence factors
A serine protease (protease A) has been purified directly from the
supernatant of V. parahaemolyticus and identified as a potential virulence
factor (Lee et al., 2002).
The protease A was a monomeric protein having a molecular mass of 43
kDa and an isoelectric point of 5.0.
Purified protease-induced tissue hemorrhage and caused death
of
experimental mice when injected intravenously and intraperitoneally (Lee et
al., 2002).
24. T3SS
Apart fromTDH or TRH, there are factors that contribute to the pathogenesis of V.
parahaemolyticus which include T3SS.
Analysis of the genome sequence of V. parahaemolyticus strain
IMD2210633
revealed two type III secretion systems (T3SS) on chromosomes 1 (T3SS1) and 2
(T3SS2).
T3SS is an apparatus used by several Gram-negative pathogenic bacteria to secrete
and translocate virulence factor proteins into the cytosol of eukaryotic cells.
V. parahaemolyticus T3SS1 is analogous to the Ysc secretion system in Yersinia, and
the V. parahaemolyticus T3SS2 is analogous to the Inv-Mxi-Spa secretion system in
Salmonella and Shigella(16).
16.Park KS, Ono T, Rokuda M, Jang MH, Okada K, Iida T, Honda T : Functional characterization of two type III secretion
systems of Vibrio parahaemolyticus. Infect Immun 72 : 6659- 6665, 2004.
25. T3SS
The Ysc secretion system is typically related to cytotoxicity and the Inv-Mxi-
Spa secretion system is associated with host cell invasion.
T3SS1 has been found in all isolated strains and is related to the cytotoxicity
observed in HeLa cells.
T3SS2 is found only in Kanagawa phenomenon (KP)-positive strains and
produces enterotoxicity which was assayed using rabbit ileal loop test.
Two known T3SS variants: observations have shown T3SS2α correlating
with tdh+/trh- strains, while T3SS2β correlates with tdh-/trh+ strains(17).
17.Noriea, Nicholas; CN Johnson, KJ Griffitt, DJ Grimes (September 2010). "Distribution of type III secretion systems in
'Vibrio parahaemolyticus from the northern Gulf of Mexico". Journal of Applied Microbiology 109 (3): 953–962.
26. Clinical disease
V. parahaemolyticus causes three major syndromes of clinical illness in
humans (Daniels et al., 2000a; Morris & Black, 1985).
1.Gastroenteritis, - Most common manifestation– characterized by watery or
bloody diarrhea, vomiting, abdominal cramps, headache, fever, general
lassitude, nausea, chills, and tenesmus.
Stool of patients with diarrhea at the acute stage are of a characteristic meat
washed/ reddish watery consistency
2. Wound infections and
3.Septicemia
27. Modes of transmission
Ingestion of improperly processed or undercooked seafood that include marine
fish, crustacean shellfish (prawns, lobsters, crabs), and molluscan shellfish is the
most common mode of transmission.
Person-to-person transmission of infection may occur from contact with an ill
individual, either directly or via secondary contamination of household water, food,
or fomites.
V. parahaemolyticus has been detected from flies in all months of the year in
Calcutta.
Mean percentage of isolation was: housefly, 14.1; blue bottle fly, 18.5; external
washing, 10.1; viscera, 22.6; flies of sweet shops, 9.7; and those from fishmarket,
22.7 (Chatterjee et al., 1978).
Flies revealed higher (4.4%) isolation of Kanagawa positive V. parahaemolyticus
strains than those of water and fish specimens (0.8%) studied.
28. Laboratory detection of V.parahaemolyticus
Detection and identification and enumeration of V. parahaemolyticus (ISO method
8914, 1990; FDA, 1998), include an inoculationof the test portion into the selective
enrichment medium APW (alkaline peptone water) and incubation at optimum
temperatures,
2.Streaking onto the selective solid medium thiosulphate citrate bile salt agar (TCBS).
3. Presumptive colonies, sub-cultured on TSA (trypticase soya agar), are subjected to
microscopic and biochemical analysis, such as Gram staining, motility, oxidase,
arginine dihydrolase, lysine decarboxylase, ortho-nitrophenyl-galactopyranoside
(ONPG),
acid–gas
from
glucose,
saccharose,
cellobiose,
and
halophilic
characteristics according to Bergey‟s Manual of Systematic Bacteriology (Baumann
and Schubert 1984).
29. Laboratory detection of V.parahaemolyticus
4.
FDA procedure includes the evaluation of V. parahaemolyticus
pathogenicity by detection of the Kanagawa phenomenon using Wagatsuma
agar, containing high-salt blood to detect the haemolytic activity of V.
parahaemolyticus thermostable direct haemolysin (TDH)-positive strains
only.
5. Vibrio species may be serotyped according to both somatic O and
capsular polysaccharide K antigens.
30. Identification of V.parahaemolyticus
Microscopic Appearance:
Gram stain : Gram negative rods straight or curved or comma-shaped of size 0.5-0.9
x 1.5-2.5 µ, forming no capsule and spores. This characteristic appearance is not
always observed when the organism is Gram-stained from solid media.
Primary Isolation Media :
Blood agar incubated in air at 35-37 C for 18-24 hr
TCBS agar incubated in air at 35-37 C for 18-24 hr
31. Identification of V. parahaemolyticus
Colony Appearance :
On blood agar colonies are 2-3 mm in diameter.
On TCBS agar, it grows with green colored colonies
due to absence of sucrose fermentation.
On
Macconkey
agar
it
produces
non-lactose
fermenting colonies.
Strains isolated from clinical specimens produce beta
hemolysis on Wagatsuma Blood Agar (human blood)
while strains isolated from environment don‟t. This is
known as Kanagawa phenomenon.
It grows well in peptone water with 8% NaCl but not at
10%.
32. Biochemical characteristics of V. parahaemolyticus
Oxidase----------------------------------------------- +
N03-NO2 + 1% NaCl------------------------------- +
Indole + 1% NaCl----------------------------------- +
Voges-Proskauer + 1% NaCl --------------------- -Urease ---------------------------------------------- --/+
Lysine decarboxylase + 1% NaCl---------------+
Ornithine decarboxylase + 1% NaCl----------+
Arginine dihydrolase + 1% NaCI----------------Fermentation of
Sucrose------------------------------------------------ -Lactose------------------------------------------------ -L-Arabinose ----------------------------------------+
Gas from glucose----------------------------------Growth in nutrient broth
0% NaCl----------------------------------------------3% NaCl---------------------------------------------+
6% NaCI----------------------------------------------+
8% NaCl----------------------------------------------+
10% NaCl---------------------------------------------Susceptibility to 0/129 ( 2,4-diamino-6,7-diisopropylpteridine phosphate)
10µg------------------------------------------------- Resistant
150 µg----------------------------------------------- Sensitive
Growth on TCBS---------------------------------------- Green colonies (18).
18.Janda JM, Powers C, Bryant RG, Abbott SL. Current Perspectives on the Epidemiology and Pathogenesis
of Clinically Significant Vibrio spp. Clin Microbiol Rev. 1988;1:245-267.
33. Serotyping of V.parahaemolyticus
V. parahaemolyticus is classified on the basis of its somatic O antigen and
capsular K antigen; the flagellar H antigens are identical in all strains of this
species (Sakazaki, 1992).
From the 13 known “O” types and more than 60 “K” types (Joseph et al.,
1982; Hisatsune et al., 1993), 75 combinations of O:K serovars of V.
parahaemolyticus are possible.
ELISA-based system is commercially available for the detection of V.
parahaemolyticus thermo stable direct haemolysin (Honda et al. 1985).
O:K serovar of each test strain was determined by agglutination tests with
specific antisera (Toshiba Kagaku Co.) or through the courtesy of H. ZenYoji.
34. Current O (somatic antigen) and K (capsular antigen) serotype scheme∗ of
V. parahaemolyticus.
O
1
2
3
4
5
6
7
8
9
10
11
K
1 5 20 25 26 32 38 41 56 58 60 64 69
3 28
4 5 6 7 29 31 33 37 43 45 48 54 56 57 58 59 65 72
4 8 9 10 11 12 13 34 42 49 53 55 63 67 73
15 17 30 47 60 61 68
18 46
19
20 21 22 39 70 74
23 44
24 52 61 66 71
19 36 40 50 51 61
∗ The serotyping kit of V. parahaemolyticus is commercially available from
TOSHIBA KAGAKU KOGYO Co. Ltd., Tokyo, Japan.
35. Molecular typing
1.16S rRNA gene analysis.
2. Polymerase chain reaction method, based on the use of combined species-specific
primers directed against the variable regions of 16S rRNA.
Multiplex PCR was established for detection of virulence genes tdh, trh and tlh.
A molecular test based on the detection of the tdh and/or trh genes, encoding for
thermo stable direct haemolysin and thermo stable-related hemolysin has been
applied to identify V. parahaemolyticus (Joseph et al. 1982; Johnson et al. 1984; Tada
et al. 1992).
Lee et al. (1995) have developed a molecular approach based on the amplification of
a DNA fragment, that is highly conservative in all strains of V. parahaemolyticus.
36. Molecular typing
PCR procedures targeting the gyrB gene, encoding the B subunit of DNA
gyrase essential for DNA replication, and the regulatory toxR gene, were
used for the specific detection of V. parahaemolyticus (Miller et al. 1987; Lin
et al. 1993; Reich and Schoolnik 1994; Kim et al. 1999).
V. parahaemolyticus can be further confirmed by the toxR PCR; the
toxR gene is species specific and can distinguish V. parahaemolyticus
from other members of the genus Vibrio (Kim et al., 1999).
FDA procedure includes the use of a gene probe targeting tdh gene for
detecting of V. parahaemolyticus (Morris et al. 1987; Yamamoto et al. 1990).
37. Molecular typing
DNA colony hybridization detects hemolysin genes. Presence or absence of the
tdh, trh1, and trh2 genes in each test strain was determined by the DNA colony
hybridization method using specific DNA probes.
Arbitrarily primed PCR (AP-PCR) , Random amplified polymorphic DNA (RAPD),
AFLP (Amplified restriction fragment length polymorphism), Ribotyping, PFGE,
MLST, MALDI-TOF mass spectrometry.
toxRS sequence determination: The toxRS region of the test DNA was
amplified by a PCR method, and the nucleotide sequence of the amplicon was
determined.
Group-specific PCR : A PCR method to specifically detect the toxRS sequence
of the new O3:K6 clone was established by a modification of the method of Wu et
al(19,20).
19.J. Okuda, M. Ishibashi, E. Hayakawa, T. Nishino, Y. Takeda, A. K. Mukhopadhyay, S. Garg, S. K. Bhattacharya, G. B. Nair, and M.
Nishibuchi, J. Clin. Microbiol. 35:3150–3155, 1997).
20.Wu, D. Y., L. Ugozzoli, B. K. Pal, and R. B. Wallace. 1989. Allele-specific enzymatic amplification of b-globin genomic DNA for
diagnosis of sickle cell anemia. Proc. Natl. Acad. Sci. USA 86:2757–2760.
38. Markers of Pandemicity
Group specific PCR(GS-PCR : Matsumoto et al. (2000) first reported the use of
group-specific PCR (GS-PCR) for rapid identification of the pandemic clone.
GS-PCR is based on the nucleotide differences at the ToxRS region identified
between the pre-1995 and post-1995 group of O3:K6 strains.
All post-1995 O3:K6 strains analyzed were 100% homologous at the nucleotide
level of the ToxRS region and differed from pre-1995 isolates by 11–14 bp
(Matsumoto et al., 2000).
The pandemic properties of serotypes O1:KUT, O4:K68, and O1:K25 were first
identified by GS-PCR analysis.
39. Group-specific PCR for identification of pandemic strains of V. parahaemolyticus. PCR
products were loaded on1%agarose gels and the amplicons visualized by ethidium bromide
staining.
Lane 1: 100 bp molecular weight standard (Gibco-BRL, USA); lane 2: negative control (nonpandemic strain AQ3810, an O3:K6 1983 isolate from Singapore); lanes 3 and 4: O3:K6
pandemic strains (VP294, 1999/Calcutta, and VP362, 2000/Calcutta, respectively);
lane 5: O4:K68 pandemic strain (VP293, 1999/Calcutta); lane 6: O1:KUT pandemic strain
(VP356, 2000/Calcutta); and lane 7: O1:K25 pandemic strain (VP343, 2000/Calcutta).
40. Markers of Pandemicity
ORF8 assay: Presence of a unique f237 filamentous phage has been proposed
to be a genetic marker for the identification of pandemic strains.
The f237 filamentous phage was initially shown to be present only in the new
O3:K6 strains isolated after 1995 from different geographical regions (Nasu et al.,
2000).
The importance of the phage significance is due to the presence of an open
reading frame (designated ORF8) encoding a protein that had no homology with
any proteins in the database.
GS-PCR assay and the ORF8 assay are now routinely used as rapid diagnostic
markers for distinction of pandemic strains from the non-pandemic V.
parahaemolyticus.
41. Detection of the ORF8 from the bacteriophage f237 by PCR. PCR products were loaded
on 1% agarose gels and the amplicons visualized by ethidium bromide staining. Lane 1:
negative control (non-pandemic strain AQ3810, an O3:K6 1983 isolate from Singapore);
lanes 2 and 3: O3:K6 pandemic strains (VP294, 1999/Calcutta, and VP362,
2000/Calcutta, respectively);
lane 4: O4:K68 pandemic strain (VP293, 1999/Calcutta);
lane 5: O1:KUT pandemic strain (VP356, 2000/Calcutta); lane 6: O1:K25 pandemic
strain (VP343, 2000/Calcutta); and lane 7: 100 bp molecular weight standard (GibcoBRL, USA).
42. Antibiotic susceptibility testing (CLSI)document M45-A
Tests of susceptibility to the following antibiotics were performed by using the
method of Bauer et al. (1): ampicillin (10 ,µg), cephalin (30 p.g),
chloramphenicol (30 , µg), colymicin (10 , µg), erythromycin (15 , µg),
gentamicin (10 , µg), kanamycin (30 , µg), lincomycin (2 , µg), methicillin (5 ,
µg), nafcillin (1 , µg), nalidixic acid (30 , µg), neomycin (30 , µg), penicillin (10
IU), polymyxin B (300 IU), streptomycin (10 , µg), and tetracycline (30 , µg)
(21).
21.Molitoris E, Joseph SW, Krichevsky MI, Sindhuhardja W, Colwell RR. Characterization and distribution of Vibrio
alginolyticus and Vibrio parahaemolyticus isolated in Indonesia. Appl Environ Microbiol. 1985 Dec;50(6):1388-94.
43. Pathogenicity was tested by KP, RIL, and
i.p. inoculation of mice
Ligated RIL. New Zealand White rabbits of either sex and weighing approximately
1.0 kg were anesthetized by intravenous injection of 45 mg of sodium pentobarbitol
per kg of body weight.
The ileum was externalized and ligated, and 2.0 ml of whole culture in brain heart
infusion broth was injected into each loop.
Test loops were separated by control intervals which were injected with sterile brain
heart infusion broth.
The ileum was returned, and the incision was closed.
After 18 to 20 h, the rabbits were sacrificed, and the loops were examined for fluid
accumulation.
Response was measured as the ratio of milliliter of fluid accumulation to centimeter
of loop length.
44. Pathogenicity was tested by KP, RIL, and
i.p. inoculation of mice
Mouse i.p. inoculations. For each strain, 0.5 ml of whole culture was
inoculated i.p. into two 18- to 21-day-old white mice, NIHINMRI CU strain.
The mice were kept in holding cages at room temperature and were
examined hourly for 10 h. They were subsequently examined daily for 10
days(21).
21.Molitoris E, Joseph SW, Krichevsky MI, Sindhuhardja W, Colwell RR. Characterization and distribution of Vibrio
alginolyticus and Vibrio parahaemolyticus isolated in Indonesia. Appl Environ Microbiol. 1985 Dec;50(6):1388-94.
45. Treatment
Rehydration is usually the only treatment needed.
There is no evidence that antibiotic treatment decreases the severity or the
length of the illness.
In severe or prolonged illnesses, antibiotics such as tetracycline or
ciprofloxacin can be used.
Choice of antibiotics should be based on antimicrobial susceptibilities of the
organism.
46. V.vulnificus
V.vulnificus is the most important pathogenic
vibrio because of its invasiveness and the
high fatality rates associated with infection.
The first indication of the existence of a new
Vibrio
species
pathogenic
for
humans
(originally called the „L+‟, or „lactose-positive
Vibrio‟ or Beneckea vulnifica) was in 1976
(22).
It was first identified and described by the
CDC in 1976 (22).
The first documented case of disease caused
by the bacterium was in 1979 by Blake et al of
the US Centers for Disease Control.
Vibrio vulnificus is a typical marine vibrio - a
slightly curved bacterium, motile by means
of a single polar flagellum.
Vulnificus means wounding.
22.Hollis DG, Weaver RE, Baker CN, Thornsberry C. Halophilic Vibrio sp. Isolated from blood cultures. J Clin Microbiol.
1976;3:425.
48. HISTORY
The first description of a fatal vulnificus infection has been attributed to
Hippocrates in the 5th century B.C. (1).
He described the case of Criton of Thasos, an island in the Agean.
This patient developed violent pain in his foot; followed by shivering and fever
rapidly soon became delirious, and the following day, the foot was noted to be
swollen and red, with small black blisters. Then he developed diarrhea and he
died on the second day.
Because Criton was an island resident, perhaps he ingested raw shellfish or food
contaminated by seawater.
49. Introduction
Vibrio vulnificus is a Gram-negative, motile curved bacterium found in marine
and estuarine environments.
It has been isolated from seawater, sediments, plankton and shellfish
(oysters, clams and crabs) located in the Gulf of Mexico, the Atlantic Coast as
far north as Cape Cod, and the entire U.S. West Coast.
Vibrio vulnificus is an emerging pathogen of humans.
It causes wound infections, gastroenteritis, or a syndrome known as primary
septicemia.
50. Epidemiology
On the basis of lipopolysaccharide (LPS) antigens, the species can be
organized into three biotypes.
Biotype 1, which accounts for almost all human infections;
Biotype 2, which consists primarily of eel pathogens; and
Biotype 3, an apparent hybrid of biotypes 1 and 2 that has been recently
isolated from fish (tilapia) handlers in Israel.
Biotype 1 was originally divided into 5 antigenic subgroups, other subgroups
are known to exist. Biotype 1 is almost invariably associated with human
disease, and one particular LPS type (1/5) is significantly more prevalent
among clinical strains.
This suggests that the presence of this LPS type itself causes increased
virulence.
51. Biotype 2
This biotype of V. vulnificus, first reported by Tison et al. (23), differs from biotype 1
(the originally described strains) in several biochemical reactions (e.g. being indole
negative) and in having a different Lipopolysaccharide type.
Biotype 2 consists of a homogeneous type of LPS.
23.Tison DL, Nishibuchi M, Greenwood JD, Seidler RJ. Vibrio vulnificus biogroup 2: new biogroup pathogenic
for eels. Appl Environ Microbiol 1982; 44: 640– 646.
52. Biotype 3
First isolated in 1999, biotype-3 strains of V. vulnificus differ from biotypes 1
and 2 in several biochemical traits (e.g. lack of salicin and cellobiose
fermentation) (24,25).
Biotype 3 causes cellulitis, necrotizing fasciitis, and osteomyelitis.
24.Bisharat N, Agmon V, Finkelstein R, et al. Clinical, epidemiological, and microbiological features of Vibrio
vulnificus biogroup 3 causing outbreaks of wound infection and bacteraemia in Israel. Israel Vibrio study
Group. Lancet 1999; 3554: 1421–1424.
25.Colodner R, Raz R, Meir I, et al. Identification of the emerging pathogen Vibrio vulnificus Biotype 3 by
commercially available phenotypic methods. J Clin Microbiol 2004; 42: 4137–4140.
53. Risk factors
Severity of V vulnificus infections (and probably the infectious dose required for
infection) depends on both bacterial and host factors.
V. vulnificus produces a number of enzymes (hyaluronidase, mucinase, DNAase,
lipase, and protease) that may facilitate pathogenesis.
In addition, the presence of a capsule appears to be associated with invasive forms of
V vulnificus. (encapsulated forms are more commonly found among clinical isolates
than among environmental isolates.(26,27).
26.Hor LI, Chang TT, Wang ST. Survival of Vibrio vulnificus in whole blood from patients with chronic liver diseases: association with phagocytosis
by neutrophils and serum ferritin levels. J Infect Dis. 1999;179:275-278.
27.Bullen JJ, Spalding PB, Ward CG, et al. Hemochromatosis, iron, and septicemia caused by Vibrio vulnificus. Arch Intern Med. 1991;151:1606-1609.
54. Risk factors
V.vulnificus is sensitive to the degree of iron bound by transferrin in a given
host, because it uses transferrin-bound iron for growth.(28,29).
Persons with elevated transferrin-bound iron saturation (greater than 70%)
or elevated ferritin levels, which includes persons with hemochromatosis,
thalassemia, or liver disease, immunosuppression and hypochlorhydria
are at increased risk for invasive infections.
28.Brennt CE, Wright AC, Dutta SK, et al. Growth of Vibrio vulnificus in serum from alcoholics: association with high transferrin
iron saturation. J Infect Dis. 1991;164:1030-1032.
29.Centers for Disease Control and Prevention. Vibrio vulnificus infections associated with raw oyster consumption -- Florida,
1981-1992. MMWR. 1993;42:405-407.
56. Modes of transmission
Oysters, the most common vehicle for V. vulnificus infections, are typically
found in estuaries and bays.
Wound infections, which are often necrotizing, are usually acquired when an
open wound is exposed to warm seawater or seafood drippings
contaminated with V. vulnificus.
Consumption of Raw or undercooked shellfish especially oysters is another
source of infection.
57. Clinical disease
Infections with V. vulnificus
1. Wound infection-Invasion is characterized by the occurrence of blister-like skin
lesions or bullae, and rapidly-spreading necrosis resembling necrotizing fasciitis.
2.Primary septicaemias following ingestion of raw seafood include pneumonia(30),
osteomyelitis,(31)spontaneous bacterial peritonitis,(32), eye infections,(33) and
meningitis (34), endometritis or fallopian tube infection.
3.Gastroenteritis
which usually develops within 16 hours of eating the
contaminated food.
30.Kelly MT, Avery DM. Lactose-positive Vibrio in seawater: a cause of pneumonia and septicemia in a drowning victim. J Clin
Microbiol. 1980;11: 278-280.
31.Vartian CV, Septimus EJ. Osteomyelitis caused by Vibrio vulnificus. J Infect Dis. 1990;161:363.
32.Holcombe DJ. Vibrio vulnificus peritonitis. A unique case. J La State Med Soc. 1991;143:27-28.
33.DiGaetano M, Ball SF, Straus JG. Vibrio vulnificus corneal ulcer. Case reports. Arch Ophthalmol. 1989;107:323-324.
34.Katz BZ. Vibrio vulnificus meningitis in a boy with thalassemia after eating raw oysters. Pediatrics. 1988;82:784-786.
58. Wound infections caused by V.vulnificus
Characteristic skin lesions associated with Vibrio vulnificus infection on the leg in a 75-year-old
patient with liver cirrhosis in whom septic shock and bacteremia developed.
B) V. vulnificus bacteremia developed one day after a fish bone injury on the fourth finger of the left
hand (arrow) in a 45-year-old patient with uremia.
C. Gram-negative curved bacilli isolated from a blood sample of the 45-year-old patient with uremia.
Photos from Hsueh, et al. Vibrio vulnificus in Taiwan. CDC Emerging Infectious Diseases Volume 10,
Number 8, August 2004.
59. Symptoms and signs associated with Vibrio. vulnificus
wound infections
Symptom/sign
%
88
88
65
29
18
18
12
6
6
Cellulitis at wound site
Bullae
Fever (>37.8 ᴼ C)
Chills
Mental status changes#
Ecchymosis
Hypotension$
Diarrhoea
Vomiting
* Adapted from Klontz et al.(35) (n=168).
# Obtundation, disorientation, or lethargy.
$ Systolic blood pressure less than 90 mmHg.
35.Klontz KC, Lieb S, Schreiber M, Janowski HT, Baldy LM, Gunn RA. Syndromes of Vibrio vulnificus infections. Clinical
and epidemiological features in Florida cases, 1981–1987. Ann Intern Med 1988; 109: 318–323.
60. VIRULENCE AND PATHOGENESIS
Virulence Factors include
* Capsule
* LPS
* Extracellular proteins & cell associated factors
Capsule:The acidic mucopolysaccharide capsule is thought to be the major virulence
factor.
Uronic acid component of the capsule is itself a strong stimulant to the release of
tissue necrosis factor by macrophages.
LPS: Cell wall of V. vulnificus contains lipopolysaccharide (36).
In vivo studies suggest this material is active and may account for the hypotension
seen in septicemia.
36.Elmore SP, Watts JA, Simpson LM, et al. Reversal of hypotension induced by Vibrio vulnificus lipopolysaccharide in the rat by
inhibition of nitric oxide synthase. Microbiol Pathogenesis 1992;13:391-397.
61. VIRULENCE AND PATHOGENESIS
Extracellular proteins & cell associated factors: Pili, hyaluronidase,
collagenase,metalloprotease,elastase,cytolysin(Hemolysin),
phospholipase,
mucinase.
The metalloprotease increases vascular permeability by releasing histamine
from mast cells and/or by activating the Hageman factor-plasma kallikreinkinin
system (37).
37.Powell JL, Wright AC, Harris AM, et al. The role of Vibrio vulnificus virulence factors in the in vitro
stimulation ofTNFa. In: proceedings of the Annual Meeting of the American Society of Microbiology (Las
Vegas, Nevada) ASM p. 78, 1994.
62. Identification of V.vulnificus
V. vulnificus infection is diagnosed by routine stool, wound, or blood culture.
Microscopic Appearance:
Gram stain : Gram negative rods straight or curved or comma-shaped of size 0.5-0.9 x
1.5-2.5 µ, forming no capsule and spores. This characteristic appearance is not always
observed when the organism is Gram-stained from solid media.
Primary Isolation Media :
Blood agar incubated in air at 35-37 C for 18-24 hr
TCBS agar incubated in air at 35-37 C for 18-24 hr
Colony Appearance :
On blood agar colonies are 2-3 mm in diameter.
On TCBS agar, it grows with green/ yellow colored colonies.
On MacConkey agar, V.vulnificus produces lactose fermenting colonies.
64. Serotyping & Molecular typing of V. Vulnificus
The identity of V. vulnificus strains may be confirmed by immunological test, such
as enzyme-linked immunosorbent assay (ELISA) with monoclonal antibody
species-specific for an intracellular antigen.
Molecular typing :
Polymerase chain reaction: It is based on the use of combined species-specific
primers directed against the variable regions of 16S rRNA, was developed for the
specific detection of V. vulnificus strains (Kim and Jeong 2001).
A rapid, specific enumeration technique for V. vulnificus, using a nonradioactive
probe, is currently being evaluated (Wright et al. 1993; FDA, 1998).
FDA procedure includes the use of a gene probe for the identification of V.
vulnificus, targeting cytotoxin, haemolysin (Morris et al. 1987; Yamamoto et al.
1990).
65. Treatment
Surgical debridement.
Antimicrobial agents most effective against V vulnificus infections include
tetracycline,(38,39) fluoroquinolones (for example, ciprofloxacin), third-generation
cephalosporins (for example, ceftazidime), and aminoglycosides (for example,
gentamicin).
The most current antimicrobial recommendation includes treatment with ceftazidime
(2 g IV tid) and doxycycline (100 mg PO or IV bid) (40) or doxycycline in
combination with ciprofloxacin or an aminoglycoside.
Early administration of antimicrobial therapy may reduce the morbidity and mortality
associated with V vulnificus infections.
38.Bowdre JH, Hull JH, Cocchetto DM. Antibiotic efficacy against Vibrio vulnificus in the mouse: superiority of tetracycline.
J Pharmacol Exp Ther. 1983;225:595- 598.
39. Fang FC. Use of tetracycline for treatment of Vibrio vulnificus infections. Clin Infect Dis. 1992; 15:1071.
40.Gilbert DN, Moellering RC, Sande MA. Sanford Guide to Antimicrobial Therapy. 29th ed. Hyde Park, Vt: Antimicrobial
Therapy, Inc; 1999.
66. Prevention
Pasteurization of oysters has been shown to reduce or eliminate V. vulnificus
without altering the taste or consistency of oysters.
Capsular polysaccharide is the major determinant of virulence.
Experimental vaccines utilizing capsular polysaccharide, conjugated to tetanus
toxoid or homologous extracellular proteins are capable of eliciting an immune
response in mice (41).
Passive immunoprophylaxis or immumotherapy may be feasible using
conjugate induced IV immune globulin (42).
41.Devi S, Hayat U, Kreger A, et al. Protection conferred by capsular conjugate vaccines of Vibrio vulnificus in a marine
model. In: Proceedings of the Annual Meeting of the American Society of Microbiology (Las Vegas, Nevada) ASM p. 150,
1994.
42. Devi S, Hayat U, Powell J, et al. Passive immunization of mice with antiserum to capsular polysaccharide-tetanus toxoid
conjugate confers protection against Vibrio vulnificus septicemia. In the Proceedings of the Interscience Conference on
Antimicrobials and Chemotherapy (Orlando, Florida) ICAAC, p. 189, 1994.
67. Characteristics of V.Vulnificus & V.parahemolyticus
Traits
Oxidase
V.Vulnificus*
Positive
V.parahemolyticus
Positive
TSI Agar medium
Slant
Stab
Gas
H2 S
N
A
---
N
A
---
LIM medium
Lysine Decarboxylation
Indole production
Motility
+
+
+
+
+
+
Ornithine decarboxylation
+
+
Arginine hydrolysis
--
--
Growth in peptone medium
0% NaCl
1
3
8
10
-+
+
---
-+
+
+
--
VP
--
--
69. V.alginolyticus
V alginolyticus is a halophilic Vibrio first recognized as being pathogenic in humans in
1973.
Wound infections account for 71% of V alginolyticus infections(44).
Ear infections ( Otitis media-most common) are also seen with this organism.
Gastroenteritis was thought to be a rare presentation accounting for 12% of
infections (44).
Other clinical syndromes reported in association with V alginolyticus infection include
chronic diarrhea in a patient with AIDS,(45) conjunctivitis, (46) and post-traumatic
intracranial infection (47).
44.Hlady WG, Klontz KC. The epidemiology of Vibrio infections in Florida, 1981- 1993. J Infect Dis. 1996;173:1176-1183.
45.Caccemese SM, Rastegar DA. Chronic diarrhea associated with Vibrio alginolyticus in an immunocompromised patient. Clin Infect Dis.
1999;29:946- 947.
46. Lessner AM, Webb RM, Rabin B. Vibrio alginolyticus conjunctivitis. Arch Ophthalmol. 1985; 103:229-230.
47. Opal SM, Saxon JR. Intracranial infection of Vibrio alginolyticus following injury in salt water. J Clin Microbiol. 1986;23:373-374.
70. V . alginolyticus
Colonies were larger (from 6-9mm) irregular in shape, transparent or
opaque, with a wavy margin on blood agar.
On TCBS agar, colonies are yellow in colour.
It has a higher salt tolerance, is VP positive and ferments sucrose.
Growth in the presence of 10% NaCl, acetoin production, and fermentation
of arabinose are important features which distinguish V. alginolyticus from V.
parahaemolyticus.
Resistance to tetracycline and chloramphenicol has been reported in a few
isolates of V alginolyticus, but all strains appear to be sensitive to
ciprofloxacin (48).
48. French GL. Antibiotics for marine Vibrios. Lancet. 1990;336:568-569.
71. Association of pathogenic Vibrio species with three
major clinical syndromes
Vibrio Species
V.parahemolyticus
V.alginolyticus
V.vulnificus
Primary septicemia Gastroenteritis
Wound infection
+
+++
++
+++
*
+++
++
+++
+
+++, most common association; ++, possible association; +, rare association.
*, The association remains to be firmly established.
Adapted from West (1989).
49.Tantillo GM, Fontanarosa M, Di Pinto A, Musti M. Updated perspectives on emerging vibrios
associated with human infections. Lett Appl Microbiol. 2004;39(2):117-26. Review.
72. V. fluvialis
V fluvialis is a halophilic Vibrio first identified in 1975 in a patient with diarrhea in
Bahrain.(50)
It is biochemically similar to Aeromonas hydrophila but can be differentiated from
this organism by its ability to grow well on media containing 6% to 7% sodium
chloride.
The largest series of V fluvialis infections involved 500 patients in Bangladesh, half
of whom were young children.(51) In that series, patients presented with diarrhea
(100%, 75% bloody), vomiting (97%), abdominal pain (75%), dehydration (67%),
and fever (35%).
V fluvialis rarely causes wound infections or primary septicemia.(44,52)
44.Hlady WG, Klontz KC. The epidemiology of Vibrio infections in Florida, 1981- 1993. J Infect Dis.
1996;173:1176-1183.
50. Furniss AL, Lee JV, Donovan TJ. Group F, a new Vibrio? Lancet. 1977;10:73-94.
51. Huq MI, Alam KMJ, Brenner DJ, et al. Isolation of Vibrio-like group, EF-6, from patients with diarrhea. J
Clin Microbiol. 1980;11:621-624.
52. Varghese MR, Farr RW, Wax MK, et al. Vibrio fluvialis wound infection associated with medicinal leech
therapy. Clin Infect Dis. 1996;22:709-710.
73. Vibrio hollisae
V hollisae, a halophilic Vibrio like species first described in 1982, most
commonly causes gastroenteritis.
Now it is named as Grimontia hollisae.
V hollisae is difficult to isolate, since it grows poorly on selective TCBS media
and it needs to be isolated from colonies on a blood agar plate.
V hollisae septicemia and wound infections have been reported but are
rare.(44,53)
44.Hlady WG, Klontz KC. The epidemiology of Vibrio infections in Florida, 1981- 1993. J Infect Dis. 1996;173:11761183.
53.Rank EL, Smith IB, Langer M. Bacteremia caused by Vibrio hollisae. J Clin Microbiol. 1988; 26:375-376.
74. Photobacterium damsela
P damsela (formerly Vibrio damsela) is a halophilic gram-negative bacillus similar
to V .vulnificus that strictly causes soft tissue infections following exposure of
wounds to brackish water or injury by saltwater animals.(54)
P damsela infections can be fulminant and are frequently fatal even in
immunocompetent hosts.
Of the 16 cases of P damsela infection reported between 1982 and 1996, 4 were
fatal.(55)
54. Barber GR, Swygert JS. Necrotizing fasciitis due to Photobacterium damsela in a man lashed by a stingray. N
Engl J Med. 2000;342:824.
55. Fraser SL, Purcell BK, Delgado B, et al. Rapidly fatal infection due to Photobacterium (Vibrio) damsela. Clin
Infect Dis. 1997;25:935-936.