Serratia marcescens

S. marcescens is a motile organism and can grow in temperatures ranging and in pH levels ranging from 5 to 9. It is differentiated from other Gram-negative bacteria by its ability to perform casein hydrolysis, which allows it to produce extracellular metalloproteinases which are believed to function in cell-to-extracellular matrix interactions. Since this bacterium is a facultative anaerobe, meaning that it can grow in either the presence of oxygen (aerobic growth) or in the absence of oxygen (anaerobic growth), it is capable of nitrate reduction under anoxic conditions. Therefore, nitrate tests are positive since nitrate is generally used as the final electron acceptor rather than oxygen. S. marcescens also exhibits tyrosine hydrolysis and citrate degradation. ==Pathogenicity==

of S. marcescens on Mueller–Hinton agar In humans, S. marcescens can cause an opportunistic infection in several sites, including the urinary tract, respiratory tract, wounds, breasts, and the eye, where it may cause conjunctivitis, keratitis, endophthalmitis, and tear duct infections. It is also a rare cause of endocarditis and osteomyelitis (particularly in people who use intravenous drugs recreationally), pneumonia, and meningitis. In silkworms, it can also cause a lethal disease, especially in association with other pathogens. In research laboratories employing Drosophila fruit flies, infection of them with S. marcescens is common. It manifests as a pink discoloration or plaque in or on larvae, pupae, or the usually starch and sugar-based food (especially when improperly prepared). A rare clinical form of gastroenteritis occurring in early infancy is caused by infection with S. marcescens. The red color of the diaper can be mistaken for hematuria (blood in the urine), which may cause unnecessary investigations by the physicians. S. marcescens causes cucurbit yellow vine disease, leading to sometimes serious losses in melon fields. Virulent strains of S. marcescens can impact honey bee colonies. ==History==

Possible role in medieval miracles Because of its red pigmentation, caused by expression of the dye prodigiosin, and its ability to grow on bread, S. marcescens has been evoked as a naturalistic explanation of medieval accounts of the "miraculous" appearance of blood on the Corporal of Bolsena, S. marcescens growth on bread, called blood bread, bloody bread, or red bread, is an uncommon but known problem in food manufacturing. Discovery S. marcescens was discovered in 1819 by Venetian pharmacist Bartolomeo Bizio, as the cause of an episode of blood-red discoloration of polenta in the city of Padua. Bizio named the organism four years later in honor of Serafino Serrati, a physicist who developed an early steamboat; the epithet marcescens (Latin for 'decaying') was chosen because of the dyestuff's rapid deterioration–Bizio's observations led him to believe that the organism decayed into a mucilage-like substance upon reaching maturity. Serratia was later renamed Monas prodigiosus and Bacillus prodigiosus before Bizio's original name was restored in the 1920s. ==Uses and misuse==

Role in biowarfare testing Until the 1950s, S. marcescens was erroneously believed to be a nonpathogenic "saprophyte", which studied it in field tests as a substitute for the tularemia bacterium, which was being weaponized at the time. On 26 and 27 September 1950, the U.S. Navy conducted a secret experiment named Operation Sea-Spray in which balloons filled with S. marcescens were released and burst over urban areas of the San Francisco Bay Area in California. Although the Navy later claimed the bacteria were harmless, beginning on 29 September, 11 patients at a local hospital developed very rare, serious urinary tract infections. One of the afflicted patients, Edward J. Nevin, died. Cases of pneumonia in San Francisco also increased after S. marcescens was released. (That the simulant bacteria caused these infections and death has never been conclusively established.) Nevin's son and grandson lost a lawsuit they brought against the government between 1981 and 1983, on the grounds that the government is immune, and that the chance that the sprayed bacteria caused Nevin's death was minute. The bacterium was also combined with phenol and an anthrax simulant and sprayed across south Dorset by US and UK military scientists as part of the DICE trials which ran from 1971 to 1975. Since 1950, S. marcescens has steadily increased as a cause of human infection, with many strains resistant to multiple antibiotics. The heparin IV flush syringes had been found to be contaminated with S. marcescens, which resulted in patient infections. The Centers for Disease Control and Prevention confirmed growth of S. marcescens from several unopened syringes of this product. S. marcescens has also been linked to 19 cases in Alabama hospitals in 2011, including 10 deaths. All of the patients involved were receiving total parenteral nutrition at the time; the two pharmacists responsible for formulating the solution were criminally charged. Ground-water flow tracing Because of its ability to be grown on agar plates into even, well coloured lawns, and the existence of a phage specific to S. marscecens, it has been used to trace water flows in karst limestone systems. Known quantities of phage are injected into a fixed point in the karst water system and the outflows of interest are monitored by conventional small-volume sampling at fixed time intervals. In the laboratory, the samples are poured onto grown S. marscecens lawns and incubated. Colourless plaques in the lawns indicate the presence of phage. The method was claimed to be sensitive at very high dilutions because of the ability to detect single phage particles. == Treatment and antibiotic resistance ==

Traditionally, infections by S. marcescens have been treated with cefepime, carbapenems (Siedner et al., 2014; Tamma et al., 2022 as cited in Tavares-Carreon et al., 2023), aminoglycoside amikacin, gentamicin and tobramycin (Bertrand & Dowzicky, 2012; Sader et al., 2014 as cited in Tavares-Carreon et al., 2023). However, recent clinical data has shown declining efficacy for gentamicin and tobramycin, part of a trend towards increasing resistance and a narrowing of treatment options. The development of these resistances to common antibiotics is partially due to adaptive resistance through overexposure and selection of resistant strains, but S. marcescens also has intrinsic resistance from sources such as lipopolysaccharide modifications, which can reduce antibiotic penetration, and adaptive resistance through biofilm production (Tavares-Carreon et al., 2023). Biofilm production increases antibiotic resistance because bacteria at the bottom of the biofilm are less exposed to antibiotics, the bacteria in the biofilm do not grow as quickly, and there are faster rates of horizontal gene transfer which allows resistance genes to spread easily within the population. In 2017, the World Health Organization listed Serratia as among the most critical group of bacteria for which new antibiotics are urgently needed due to its resistance to multiple drugs and threat to hospitals, nursing homes, and patients who use ventilators and blood catheters. S. marcescens skin infections are uncommon, but may be suspected in cases of cellulitis in immunocompromised individuals, particularly when conventional antibiotics are ineffective. It is also resistant to many other antibiotics, including penicillin, cephalosporin, tetracycline, macrolide, nitrofurantoin, and colistin. Broad-spectrum antibiotics such as third-generation cephalosporins, fluoroquinolones, and imipenem/cilastatin are indicated for treatment of S. marcescens skin infections. == Biofilms ==

Phloretin may reduce the virulence of S. marcescens by disrupting quorum sensing and biofilm formation. When treated with chloramphenicol, S. marcescens biofilms demonstrated significant reductions in growth. Genetic studies have demonstrated a role for type I pili (fimbriae) in S. marcescens biofilm formation. ==See also==