Corynebacterium Infections

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Background

Corynebacteria (from the Greek words koryne, meaning club, and bacterion, meaning little rod) are gram-positive, catalase-positive, aerobic or facultatively anaerobic, generally nonmotile rods. The genus contains the species Corynebacterium diphtheriae and the nondiphtherial corynebacteria, collectively referred to as diphtheroids.[1] Nondiphtherial corynebacteria, originally thought mainly to be contaminants, increasingly are recognized as pathogenic, especially in immunocompromised hosts.

In approximately the mid-1980s, taxonomic changes were made to diverse genera previously included within the coryneform groups. The reclassification is based on the degree of homology of RNA oligonucleotides between groups. Based on this reclassification, for example, Corynebacterium haemolyticum became Arcanobacterium haemolyticum and the JK group became Corynebacterium jeikeium.[2]  Van den Velde and colleagues have suggested that species of corynebacteria more correctly would be identified based on their cellular fatty acid profiles (ie, for the C14 to C20 fatty acids).[3]

Advances in molecular biology and genome analysis allow for detailed descriptions of DNA-binding transcription factors and transcriptional regulatory networks. This first was described for Corynebacterium glutamicun. Web-based resources are available online at CoryneRegNet.[4]  

Prior to the 1990s, the incidence of diphtheria had been declining. However, an epidemic of diphtheria in the former Soviet Union first was noticed in the Russian Republic in 1990 and then spread to the other newly independent states, peaking in the mid-1990s. In some endemic locations, such as India, 44% of throat and nasal swabs tested positive for C diphtheriae and Corynebacterium pseudodiphtheriticum.[5] Today, the more common scenario is nondiphtherial corynebacterial bacteremia associated with device infections (venous access catheters, heart valves, neurosurgical shunts, peritoneal catheters), as well as meningitis, septic arthritis, and urinary tract infections.

With increasingly frequent global migration and increasing numbers of refugees, some countries are reporting increasing incidences of C diphtheriae infections. This seems to be particularly prevalent in refugees from countries where the public health system has deteriorated, such as Haiti, Venezuela, Afghanistan and Pakistan.[6, 7, 8, 9]

For more information about C diphtheriae infections, please see Diphtheria.

Most recently, an increase in nondiphtherial corynebacterial infections of the skin and soft tissues has been reported.[10, 11, 12, 13, 14, 15, 16, 17, 18]  This includes eye infections producing corneal thickening and toxic epidermal necrolysis.[19]

Nondiphtherial corynebacteria also cause chronic and subclinical diseases in domestic animals and can lead to significant economic losses for farmers. Examples of widespread and difficult-to-control infections include Corynebacterium pseudotuberculosis caseous lymphadenitis in sheep, goats, and alpacas; C pseudotuberculosis ulcerative dermatitis in cattle; and urinary tract infections and mastitis (affecting milk production) in cattle due to infection with Corynebacterium renale, Corynebacterium cystidis, Corynebacterium pilosum, and Corynebacterium bovis.[20, 21]

Pathophysiology

C diphtheriae

C diphtheriae infection typically is characterized by a local inflammation, usually in the upper respiratory tract, associated with toxin-mediated cardiac and neural disease. Three strains of C diphtheriae are recognized, in decreasing order of virulence: gravis, intermedius, and mitis. These strains all produce an identical toxin, but the gravis strain potentially is more virulent because it grows faster and depletes the local iron supply, allowing for earlier and greater toxin production. Toxin production is encoded on the tox gene, which, in turn, is carried on a lysogenic beta phage. When DNA of the phage integrates into the host bacteria's genetic material, the bacteria develop the capacity to produce this polypeptide toxin.

The tox gene is regulated by a corynebacterial iron-binding repressor (DtxR). In the presence of ferrous iron, the DtxR-iron complex attaches to the tox gene operon, inhibiting transcription. In an iron-poor environment, the DtxR molecule is released and the tox gene is transcribed (see the illustration below).



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The corynebacterial tox gene is regulated by the corynebacterial iron-binding repressor, labeled DtxR. Binding of ferrous iron to the DtxR molecule fo....

The toxin is a single polypeptide with an active (A) domain, a binding (B) domain, and a hydrophobic segment known as the T domain, which helps release the active part of the polypeptide into the cytoplasm. In the cytosol, the A domain catalyzes the transfer of an adenosine diphosphate-ribose molecule to one of the elongation factors (eg, elongation factor 2 [EF2]) responsible for protein synthesis. This transfer inactivates the factor, thereby inhibiting cellular protein synthesis. Inhibiting all the protein synthesis in the cell causes cell death.

In this manner, the toxin is responsible for many of the clinical manifestations of the disease. As little as 0.1 µg can cause death in guinea pigs. In 1890, von Behring and Kitasato demonstrated that sublethal doses of the toxin induced neutralizing antibodies against the toxin in horses. In turn, this antiserum passively protected the animals against death following challenge infection. By the early 1900s, treating the toxin with heat and formalin was discovered to render it nontoxic. When injected into recipients, the treated toxin induced neutralizing antibodies. By the 1930s, many Western countries began immunization programs using this toxoid.

Adhesion of pathogenic corynebacteria to host cells is a crucial step during infection. Adhesion to host cells is mediated by filaments called fimbrae or pili; the minor pilins SpaB and SpaC are specific adhesins that covalently bind the bacteria to the cell membranes of the respiratory epithelium.[22]

More recently, iron levels have been shown to regulate the adhesion properties of the bacteria; iron-limited conditions promote changes in the cell-surface residues, leading to increased hemagglutination activity and decreased binding to glass.[23]

The disease occurs mainly in temperate zones and is endemic in certain regions of the world. Most US cases are sporadic or occur in nonimmunized persons. Humans are the only known reservoir for the disease. The primary modes of dissemination are by airborne respiratory droplets, direct contact with droplets, or infected skin lesions. Asymptomatic respiratory carrier states are believed to be important in perpetuating both endemic and epidemic disease. Immunization reduces the likelihood of carrier status.

Bacteria usually gain entry to the body through the upper respiratory tract, but entry through the skin, genital tract, or eye also is possible. The cell surface of C diphtheriae has three distinct pilus structures: the main pilus shaft (SpaA) and two small pili (SpaB, SpaC). Adherence to respiratory epithelial cells can be greatly diminished by blocking production of these two minor pili or by using antibodies directed against them.[24]

In most cases, C diphtheriae infection grows locally and elicits toxin rather than spreading hematogenously. The characteristic membrane of diphtheria is thick, leathery, grayish-blue or white and composed of bacteria, necrotic epithelium, macrophages, and fibrin. The membrane firmly adheres to the underlying mucosa; forceful removal of this membrane causes bleeding. The membrane can spread down the bronchial tree, causing respiratory tract obstruction and dyspnea.

The toxin-induced manifestations involve mainly the heart, kidneys, and peripheral nerves. Cardiac enlargement due to myocarditis is common. The kidneys become edematous and develop interstitial changes. Both the motor and sensory fibers of the peripheral nerves demonstrate fatty degenerative changes and disintegration of the medullary sheaths. The anterior horn cells and posterior columns of the spinal canal can be involved, and the CNS may develop signs of hemorrhage, meningitis, and encephalitis. Death mainly is due to respiratory obstruction by the membrane or toxic effects in the heart or nervous system.

The epidemiology of C diphtheriae infection has been changing, and increasing numbers of skin, pharyngeal, and bacteremic infections with nontoxigenic bacteria have been reported. Among 828 cultures of nontoxigenic C diphtheriae isolated from different regions of Russia from 1994-2002, 14% carried the gene for the toxin.[25] Molecular characterization based on polymerase chain reaction (PCR) of some of these nontoxigenic strains have demonstrated that the bacteria often contain functional DtxR proteins, which potentially could produce toxin.[26]

Other corynebacteria (ie, diphtheroids)

Nondiphtherial corynebacteria are ubiquitous in nature and commonly colonize human skin and mucous membranes. Only recently has the role of these organisms in human infections been appreciated. In the past, many of these organisms cannot be speciated or typed easily, even in research laboratories; advances in PCR technology are improving our ability to identify these bacteria. Coyle and Lipsky in 1990 reviewed some of the common coryneform bacteria that cause infections.[2]

Specific pathogenic groups or species include the following:

Since then, more than 80 species have been described,[27, 28]  of which two thirds are either pathogenic in animals, especially in livestock, or can be transmitted to humans by zoonotic contact. Depending on the species, both skin and internal-organ systems can be affected, particularly in patients who are elderly, are immunosuppressed, or have multiorgan dysfunction. Recent genomic analyses of diphtheroids demonstrated diversified genomic island containing genes for virulence and multidrug resistance.[15]  This helps explain why some (eg, group D2) are highly resistant and require susceptibility testing for optimal treatment.

Epidemiology

Frequency

United States

C diphtheriae

In immunized persons, the rate of C diphtheriae infection since 1980 has been extremely low (< 5 cases per 100,000 population). Although infection can occur in immunized persons, prior immunization decreases disease frequency and severity. However, disease incidence started to fall even before the widespread use of toxoid. This decline may have been due to a decreasing incidence of bacterial carriers. In addition, immunized persons are less likely to be carriers of toxigenic phages.

Persons who never have been immunized or those incompletely immunized or with waxing immunity are at an increased risk for infection. In the United States, this group mainly consists of poorer individuals and immigrants.

Diphtheroids

Infections with nondiphtherial corynebacteria are being reported more frequently, especially those associated with medical devices such as intravascular catheters, artificial valves, and CNS drainage devices.

Moazzez et al (2007) found that 16% of breast abscesses in an urban county hospital were due to diphtheroids.[29]

International

C diphtheriae infection: In the early 1990s, the World Health Organization (WHO) reported that diphtheria was still endemic in many parts of the world (eg, Brazil, Nigeria, the Indian subcontinent, Indonesia, Philippines, some parts of the former Soviet Union [especially St. Petersburg and Moscow]), with epidemics also reported in republics of the former Soviet Union. The February 2000 supplement (vol.181) of the Journal of Infectious Diseases contains an in-depth evaluation of the epidemic.[30]

The Kyrgyz Republic experienced a widespread resurgence of diphtheria from 1994-1998. Among 676 patients hospitalized with respiratory diphtheria, 163 (24%) were carriers, 186 (28%) had tonsillar forms, 78 (12%) had combined types or delayed diagnosis, and 201 (30%) had severe forms. The highest age-specific incidence rates occurred among persons aged 15 years to 34 years; 70% of cases were among those aged 15 years or older. Myocarditis occurred among 151 patients (22%), and 19 patients died (case fatality rate of 3%).[31]

In another epidemic in the Republic of Georgia from 1993-1996, 659 cases and 68 deaths were reported (case fatality rate of 10%). More than 50% of the cases and deaths were in children aged 14 years and younger (case fatality rate of 16%) and in adults aged 40 years to 49 years (case fatality rate of 19%).[32]

During 2007-2008, 10 European countries screened patients with respiratory infections with throat swabs; carriage rates for nontoxigenic Corynebacterium organisms ranged from 0 to 4 cases per 1000 patients.[33]

Sporadic C diphtheriae infections are reported annually. These include skin and bloodstream infections. A review of 85 isolates from the United Kingdom from 1998-2003 revealed that most the reports came from one hospital in London, suggesting that the true incidence may be higher.[34]

Another review of C diphtheriae infections in Brazil and South America emphasized a shift in biotype, with an increase in the dissemination of an atypical sucrose-fermenting biotype, which appears to have an enhanced ability to colonize and to spread.[35]

In New Zealand, C diphtheria infections were associated with infective endocarditis in children in 12% of cases (10 of 85 cases) from 1994-2012.[36]

Diphtheroids

Infections with the nondiphtherial corynebacteria are reported worldwide.[37, 38]  Some (eg, group D2) originally reported in Europe now are found in the United States, whereas the JK group initially reported in the United States is found in Europe.

Egwari et al (2008) found that, in east Africa, 9.7% of odontogenic infections that progressed to sepsis were due to diphtheroids.[39]

The incidence of C ulcerans infections in the United Kingdom associated with contact with exposed animals has increased since approximately 1990, becoming more common than C diphtheriae infections.[40]

C ulcerans also has been reported in Latin America and one fatal case was noted in Brazil in 2008, in an elderly woman with disseminated disease resistant to penicillin and clindamycin.[41]

Mortality/Morbidity

C diphtheriae

Mortality rates are highest at the extremes of age and in insufficiently immunized persons. However, even partial immunization confers a reduced risk for severe disease. Death usually occurs within the first week, either from asphyxia or heart disease.

Immunity to diphtheria waxes in the absence of booster injections of toxoid or natural infection. Therefore, persons traveling to endemic areas should receive booster injections. At one time, diphtheria immunization was considered lapsed if more than 4 years had elapsed since the last booster. This estimate probably is still relevant for persons traveling to high-risk areas, particularly those in high-risk jobs, such as medical personnel. Otherwise, the routine recommendation is for booster injections every 10 years. Annual updates are made each year by the CDC. A complete Adult Immunization Schedule is available from the CDC's National Immunization Program.

Diphtheroids

These infections tend to occur in patients who are elderly, neutropenic, or immunocompromised or who have prosthetic devices (eg, heart valves, dialysis catheters, neurologic shunts, joint replacements).[42, 43, 44, 45]  Multidrug resistant strains have been reported to cause fatal sepsis.[46]

Race

C diphtheriae

The respiratory form of this disease has no racial predilection. Since 1972, the prevalence of the cutaneous form of the disease has increased in the United States, with a high attack rate among Native Americans and in indigent areas where crowding and poor personal and community hygiene are common. Three outbreaks of C diphtheriae infection, 86% of which were cutaneous, were recorded in Seattle's Skid Road from 1972-1982.[47]

Diphtheroids

No racial predilection exists.

Sex

No sexual predilection is reported for any of the corynebacterial diseases.

Age

C diphtheriae

The incidence of infection in children who are not immunized is reported as 70 times higher than in children who have received primary immunization. In the recent epidemics in the republics of the former Soviet Union, the high rate of infection among adults aged 40 years to 49 years has been attributed to their low levels of immunity.

Diphtheroids

Infections are reported in children and elderly persons.

Patient Education

Vaccination is the key to preventing C diphtheriae infections. Public health services and individual physicians are important resources for providing appropriate treatments. Vaccination is especially important for high-risk groups (eg, children, elderly individuals, immigrants from areas of continued endemic infections).

Infections with other diphtheroids are becoming an increasingly important problem in immunocompromised individuals; updated education of physicians caring for these patients is needed. Perhaps most important is to have a higher index of suspicion where reports of Corynebacteriae spp are reported by the microbiology lab to be contaminants.[48]

 

History

C diphtheriae

Respiratory: After an incubation period of 2 days to 4 days, patients typically report upper respiratory tract symptoms (eg, nasal discharge, sore throat). The posterior pharynx and tonsillar pillars most often are involved. Onset often is sudden, with low-grade fevers, malaise, and membrane development on one or both tonsils, with extension to other parts of the respiratory system.

Cardiac: The toxic effect in the myocardium characteristically occurs within 1 week to 2 weeks following onset of infection, often when the upper respiratory tract symptoms are improving. Manifestations are due to arrhythmias and congestive heart failure (CHF).

Neurologic: Neurologic symptoms can occur immediately or after several weeks. Bulbar symptoms generally occur within the first 2 weeks after disease onset and can range from mild symptoms (eg, difficulty swallowing) to bilateral symmetric paresis of the palatal and ocular muscles. The bulbar symptoms may remit or progress to paralysis of the proximal and then distal skeletal muscles over the next 30 days to 90 days. Although recovery can be very slow, patients generally regain complete neurologic function. Secondary complications include aspiration from bulbar paralysis and bronchopneumonia from respiratory muscle dysfunction.

Skin: Cutaneous infections can occur, often in more tropical climates, presenting as nonhealing ulcers. A recent surveillance study of Native Americans presenting to the Indian Health Service clinics in South Dakota recovered C diphtheriae from six (5%) of the 133 patients, one of whom had skin ulcers. In comparison, a retrospective review of C diptheriae infectious casesin French Guiana from 2016-2021 demonstrated that 61/64 had cutaneous ulcers.

Diphtheroids

Because these corynebacteria also are pathogenic in animals (eg, C ulcerans, C pseudotuberculosis, C ovis), a history of exposure to sick animals or to animal products (eg, milk, offal, hides) is common. C ulcerans generally causes respiratory symptoms, whereas C ovis produces a suppurative lymphadenitis.

In hosts colonized with diphtheroids (eg, groups D2, JK), bacteria can be recovered both from skin and mucosal surfaces. Corynebacterium striatum and C pseudodiphtheriticum (or C hofmannii) are normal inhabitants of the anterior nares and skin. Symptoms relate to the organ system affected. Immunocompromised patients appear to have higher colonization rates than healthy persons and may be at a greater risk of developing an infection after being colonized.[22] Bittar et al demonstrated that children with cystic fibrosis in France often were colonized by C pseudodiphtheriticum, while healthy children were not.

Antimicrobial resistance is also more common in isolates from immunosuppressed patients. Bnaya et al[14]  reported that 30% of peritoneal dialysis patients (9/30) with nontubulous peritonitis demonstrated diphtheroid or corynebacteria spp. Catheter removal was required in most patients.

The methods of transmission for nondiphtherial corynebacteria are incompletely understood. Transmission from patient to patient, from colonized hospital staff to patients, and from environmental contamination to patients have all been suggested. In antibiotic-resistant corynebacteria, transmission of the plasmid responsible for the resistance may be important.

Physical

C diphtheriae - Respiratory signs

Nasal infection may present as serosanguineous or seropurulent drainage.

With tonsillar and pharyngeal infection, exudates coalesce to form the characteristic pseudomembrane of diphtheria.

The membrane usually is grayish-white, although it can become blackish or greenish with necrosis (see the photograph below).



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The characteristic thick membrane of diphtheria infection in the posterior pharynx.

The extent of disease correlates with the severity of symptoms. Extension of the membrane to the posterior pharyngeal wall, soft palate, or nasopharynx is associated with profound malaise, weakness, cervical adenopathy, and swelling (see the photograph below), which can distort the airway and cause stridor.



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Cervical edema and cervical lymphadenopathy from diphtheria infection produce a bullneck appearance in this child. Courtesy of Immunize.org, formerly ....

Symptoms of hoarseness, dyspnea, stridor, and a loud brassy cough are associated with extension into the larynx and bronchial tree.

Edema and membrane formation can cause further respiratory distress and respiratory muscle fatigue, requiring intubation.

In fatal diphtheria, the airways are edematous, with necrosis of the epithelium covered by the pseudomembrane, and the lungs are hemorrhagic.

C diphtheriae - Cardiac signs

Subtle evidence of myocarditis may occur in many patients, but 10% to 25% of patients develop clinical cardiac dysfunction.

Signs of CHF (eg, cardiomegaly, volume overload) are not uncommon.

C diphtheriae - Nervous system signs

Signs of cranial nerve dysfunction can occur within a few days of disease onset, with paralysis of the soft palate and posterior pharyngeal wall causing dysphagia and regurgitation.

Although the motor component is usually affected most severely, both sensory and motor nerves are affected by the peripheral neuritis that occurs later.

The symptoms start in the proximal muscle groups of the extremities and spread distally.

In mild cases, only the hip girdle muscles may be affected; these patients have trouble getting out of a chair unassisted. In these patients, the motor reflexes of the lower extremities may be normal.

In the most extreme cases, respiratory muscle dysfunction occurs and patients may require respiratory support.

Interestingly, reports show that the paralysis disappears at the same rate that it appears.

Even in extremely serious cases, the neuropathy is reversible with few or no sequelae.

In severe cases, the paralysis can spread to the trunk and cause temporary bowel and bladder dysfunction.

Paresthesias, which mainly occur distally, are the most commonly reported sensory abnormalities.

C diphtheriae - Skin signs

C diphtheriae can cause skin infections with nonhealing ulcers.

A vesicle or pustule develops initially and progresses to one or more punched-out lesions that measure from a few millimeters to several centimeters, with curved elevated margins.

The lesions are initially painful and may be covered with eschar.

After a few weeks, the lesions become painless and often have a serosanguineous exudate.

Diphtheroids

Signs of diphtheroid-associated infection relate to the affected organ systems. Species of corynebacteria recovered from skin ulcers include C ulcerans, C bovis, and A haemolyticum. Those associated with bacteremia and sepsis include C pyogenes; C bovis; Corynebacterium xerosis; and groups D2, E, and JK. Case reports depict that these organisms are associated with endocarditis, prosthetic device infection, pneumonia, septic arthritis, and osteomyelitis.

Type D2 originally was identified as a pathogen causing chronic or recurrent cystitis, bladder stones, and pyelonephritis. People with prior urinary tract abnormalities or who have recently undergone urologic procedures are at highest risk for this disease. C urealyticum has been associated with chronic nephrolithiasis and renal failure.[49]

A haemolyticum is reported to cause as many as 10% of all pharyngitis cases in patients aged 10-30 years. These bacteria are capable of producing an extracellular toxin that can cause an erythrogenic rash associated with the pharyngitis.

C ulcerans usually causes skin infections but occasionally is associated with pharyngitis and respiratory disease. In 1996, a 54-year-old, otherwise healthy woman in Indiana who never had received diphtheria immunization developed a membranous pharyngitis with a toxin-producing strain of these bacteria.[50]  A review of clinical samples from the National Microbiology Laboratory in Canada published in 2005 demonstrated C ulcerans isolates from blood cultures.[51]

C striatum is an emerging nosocomial pathogen.[16]  It has been found on catheters in patients who are neutropenic and have malignancies and has been recovered from the blood of patients with pleuropulmonary infections, endocarditis, and peritonitis. C striatum found in 11 hospitalized patients with COPD exacerbations and pneumonia was found to be multidrug resistant.[17]

In one heart transplant patient, C striatum repeatedly was cultured from sputum and bronchial lavage fluid.[42] One case of C striatum meningitis was reported in 2005.[52]

C pseudodiphtheriticum infection also is found in immunocompromised hosts, associated with both native and prosthetic valve endocarditis, pneumonia, lung abscesses, tracheobronchitis, and suppurative lymphadenitis. In 1995, Manzella and colleagues reviewed the clinical and microbiological features of 17 cases of bronchitis and pneumonia due to C pseudodiphtheriticum that required hospitalization.[53] A more recent study from Brazil found C pseudodiphtheriticum caused urinary tract infections in 29%, respiratory infections in 27%, and intravenous access site infections in 19%.[54]

Group JK can be found on the skin of healthy people. Patients with prolonged hospitalization, neutropenia, or on a prolonged course of antibiotics have a high prevalence for highly resistant JK bacteria. The most common manifestation is endocarditis with bacteremia, often associated with indwelling catheters or artificial valves. A recent review of C JK endocarditis demonstrated that most were treated with many weeks of combined antibiotic therapies, including vancomycin, erythryomycin, ceftazidime, rifampin, and doxycycline.[18]

Corynebacteria often is found in the semen of men with inflammatory prostatitis; Türk et al found that more than half of these were isolates were Corynebacterium seminale.[55] However, diphtheroids can be found in the semen both of healthy men and those with chronic prostatitis syndrome.[56]

Moazzez et al (2007) found that 16% of breast abscesses in an urban county hospital were due to diphtheroids.[29] Granulomatous mastitis due to Corynebacterium group G, diagnosed by fine-needle aspirate and culture, was reported by Mathelin et al (2005).[57]  Williams et al (2021)[13]  found that 52% (22/44) of bacteria in granulomatous mastitis were diphtheroids, corynebacteria and cutibacteria species. In this review, clarithryomycin was the most commonly used antibiotic. 

Cases of Corynebacterium macginleyi keratitis following eye surgery have been reported.[58] In these cases, the bacteria was relatively resistant to extended-spectrum penicillins and fluoroquinolones.

Corynebacterium resistens is a newly described, multidrug-resistant species associated with fatal bacteremia in immunocompromised patients in Japan.[59]

Laboratory Studies

C diphtheriae

Obtain clinical specimens and information regarding the patient's contacts.

Obtain a CBC count and urinalysis because patients often have a moderate elevation in leukocytes and may have mild proteinuria (1+ to 2+ by dipstick).

In the past, C diphtheriae grew on a nutritionally inadequate medium devised by Friedrich Loeffler; the diphtheria organisms initially outgrew the other throat flora. With the Loeffler stain, the bacteria show metachromatic granules and a palisading morphology said to resemble Chinese characters.

Today, diagnoses of C diphtheriae infection can be confirmed definitively by culture on blood agar or selective tellurite media, which inhibits the growth of normal oral flora; C diphtheriae develops a black colony with a characteristic gray-brown halo. Potentially toxigenic species (eg, C diphtheriae, C ulcerans, C pseudotuberculosis) have cystinase but not pyrazinamidase activity.

Traditionally, toxin production was demonstrated by injecting toxin material into guinea pigs and watching to see if they died. The Elek plate test for biologic activity of the toxin, an immunoprecipitation test, was developed in 1949 and replaced the in vivo guinea pig test. Even though the test was recently modified and standardized, interpretation can be difficult.

Other recent tests for toxigenicity include PCR detection of the A and B subunits of the tox gene, PCR detection of the A fragment of the toxin, and rapid enzyme immunoassay using a monoclonal antibody to the A fragment. However, some studies identify bacterial isolates that contain the A fragment of the toxin, which is not biologically active. Reports from Russia and Ukraine suggest that the number of these false-positive results is increasing.

The modified Elek tests take 24 hours to 48 hours for results; PCR detection and the enzyme immunoassay test reportedly yield results within a few hours.

Epidemiologic studies also have used typing of ribosomal bacterial RNA to detect and type strains of pathogenic corynebacteria.[60]

Diphtheroids

In the past, diphtheroid species were identified by culture. A wide variety of colony types may be observed. Many require special media to grow (eg, sheep's blood agar, Loeffler or tellurite plates) and some grow quite slowly. The colony types also have a range of biochemical characteristics, making identification difficult. For this reason, clinical suspicion of diphtheroid infection requires communication with the microbiology laboratory so that the appropriate cultures can be processed. More recently, 16S ribosomal ribonucleic acid (rRNA) probes have been designed for the identification of both genus and species of corynebacteria. A minireview by Bernard (2012)[27]  also discusses laboratory techniques for speciation, such as matrix-assisted laser desoprtoin ionization - time of flight (AMLDI-TOF), where bacterial proteins are liberated from the cell, ionized, detected by mass spectrometry, and the resulting pattern compared to a bacterial protein database. 

As mentioned above, toxigenic strains of C ulcerans and C pseudotuberculosis are reported. Therefore, consider testing for toxin production.

Cerebrospinal fluid (CSF) abnormalities include pleocytosis and elevated protein levels; the degree of inflammation in the CSF does not appear to correlate with the degree of neurologic dysfunction.

Several systems for isolating and detecting specific bacterial proteins may be useful for identifying corynebacterium species.[61] A multiplex PCR system for C diphtheriae, C ulcerans, and C pseudotuberculosis has been reported; it can simultaneously identify and determine the toxigenicity of these corynebacterial species with zoonotic potential.[62, 63]

Genomic analysis of Corynebacteriae diphtheroids specides demonstrated that all of the 40 strains studied contained bacterophage components integrated into the genome, some of which were intact and contained the tox gene. In addition, diversified genomic islands were seen across the dataset, containing genes for both virulence and multi-drug resistance.[28]

Other Tests

Electrocardiography

ECG changes include conduction abnormalities and repolarization changes. As many as 30% of patients with respiratory tract diphtheria demonstrate abnormal ECG results within a week to 10 days of developing respiratory symptoms.

Patients who develop clinical or ECG changes associated with cardiac disease have a mortality rate that is three times to four times higher than patients with normal ECG results.

Autopsy

At autopsy, the heart is pale brown, soft, and enlarged, with a characteristic streaky appearance.

Neutral fat accumulations are observed in approximately 50% of patients, with extensive hyaline degeneration and necrosis with inflammatory changes.

Electron microscopy demonstrates swollen disorganized mitochondria that contain dense osmophilic granules.

The coronary vessels, valves, endocardial surfaces, and epicardial surfaces are unaffected.

Microscopic examination of the affected nerves shows myelin sheath and axon degeneration. In particular, the large myelinated fibers are affected, demonstrating characteristic segmental demyelination.

In fatal cases, the kidneys demonstrate interstitial edema and necrosis at autopsy.

Medical Care

For the initial office visit or emergency department treatment, see Diphtheria in the Medscape Reference Emergency Medicine section.

C diphtheriae

Since the early 1900s, diphtheria antitoxin (DAT), produced in horses, has been the mainstay of therapy. The antiserum works only to neutralize the toxin before it enters the cell. The antiserum is thought to be more effective in less severely ill patients and in those who are treated earlier in the disease course. Therefore, more severely ill patients and those with longer symptom duration are given higher doses than those with less severe disease of shorter duration. Whether this is an effective way of dosing the antiserum never has been tested.

Many people show signs of hypersensitivity reactions to the horse antiserum, and a test dose usually is given, with epinephrine available in case the patient has a severe reaction. However, because the mortality rate associated with antiserum has declined markedly, desensitization with increasing doses of antiserum is recommended.

Antibiotics treatment is the second arm of treatment. The goal is both to kill the organism and to terminate toxin production. In the past, many antibiotics had been effective, including penicillin, erythromycin, clindamycin, rifampin, and tetracycline; erythromycin or penicillin is the treatment of choice and usually is given for 14 days.

More recently, increasing antibiotic resistance has been reported. In a population genomics study by the Pasteur Institute of C diphtheriae strains from around the world, pencillin resistance was reported in 17% of cases, and 10% were resistant to three or more antimicrobial classes.[64]

Supportive care also is important, including rest, airway management, observation for development of secondary lung infections, and management of cardiac and neurologic disease complications.

Diphtheroids

Antibiotics are the treatment of choice for nondiphtherial corynebacteria infections. Many species and groups are sensitive to various antibiotics, including penicillins, macrolide antibiotics, rifampin, and fluoroquinolones. However, antibiotic susceptibility can vary, and susceptibility testing is recommended.

A retrospective study in Japan compared clinical characteristics of patients with Corynebacterium bacteremia. Of the 115 cases reviewed, 52% were true bacteremia and 48% were contamination. C striatum and C jeikeium were more likely to cause true bacteremia compared to other Corynebacterium species. These pathogens commonly were seen in those with hematologic malignancies and neutropenia. At 90 days, mortality rates were 34% for C striatum, 30% for C jeikeium, and 0% for other species. Given the high mortality rates, true bacteremia assessment is imperative when C striatum or C jeikeium is detected in blood cultures, especially in those with hematologic malignancies.[65]

A review by Riegel et al on identification and antimicrobial sensitivity in 415 corynebacterial isolates from clinical specimens of patients hospitalized in Strasbourg, France, demonstrated that many species or groups were susceptible to ampicillin, cefotaxime, and rifampicin.[66] Many species or groups were resistant to erythromycin, and 2 groups (ie, JK, C urealyticum) were resistant to nearly every drug tested.

Another review, by Spanik et al, examined risk factors for disease with corynebacteria.[67] Of 123 episodes of breakthrough bacteremia during antibiotic prophylaxis in patients with cancer, 10% were from corynebacteria causing indwelling catheter infections. In this review, catheter removal and modification of antimicrobial therapy, depending on susceptibility testing, were independent risk factors for an improved outcome.

In another review of antimicrobial treatment options for corynebacterial mastitis, Corynebacterium kroppenstedtii was susceptible to most antibiotics except beta lactams, while Corynebacterium tuberculostearicum was resistant to most antibiotics.[11]  Clarithryomycin also has been used for treatment of granulomatous mastitis, although typically therapy must be continued for months.[13]

Surgical Care

The mainstay of treatment for these infections is nonsurgical. However, a case report discussed necrotizing lymphadenitis that was unresponsive to repeated antibiotic therapy, requiring surgical drainage and adequate debridement of the infected area.[68]

Consultations

The World Health Organization expanded its network of laboratories after the outbreaks of diphtheria in the Russian republics; the Diphtheria Surveillance Network integrates epidemiologic and microbiologic aspects of potentially toxigenic corynebacteria.[60]

In 2014, the WHO published a flowchart for case classification of suspected or documented corynebacterial infections.[69]  This includes infections of C diphtheriae as well as diphtheroid organisms.

The US Centers for Disease Control and Prevention (CDC) is the source for antitoxin (ie, DAT) in the United States. If treating suspected cases of diphtheria, contact the diphtheria duty officer at 800-CDC-INFO (800-232-4636).

Report all suspected cases of diphtheria to local and state health departments. Local infectious disease specialists who work with the CDC are available 24 hours a day through the local public health department for help with symptoms and disease management.

Cardiologists, pulmonary specialists, and neurologists may help in the care of patients who have specific disease complications.

Prevention

Vaccination

As mentioned above, childhood immunization is the prevention method of choice. Diphtheria/tetanus/pertussis (DTP) vaccine, given at ages 2, 4, and 6 months; at age 15 months to 18 months; and at least 5 years later (age 4-6 y) is the immunization regimen recommended by the American Academy of Pediatrics, the Advisory Committee on Immunization Practices, and the American Academy of Family Physicians.

Unvaccinated people older than 7 years or people whose immunization status is unknown should receive three doses of the adult formulation of the tetanus-diphtheria toxoid (Td). The first two doses are given 4 weeks to 8 weeks apart, and the third dose is given 6 months to 12 months later.

The first booster dose of Td should be given at least 5 years after the last immunization and every 10 years thereafter. A reduced antigen booster (combined with tetanus and pertussis) is available that is highly immunogenic with low reactogenicity.[70]

Adverse reactions include local induration, pain, redness, and, occasionally, low-grade fevers. Serum sickness hypersensitivity reactions are reported in some adults.

Vaccination coverage levels are monitored by the CDC National Immunization Survey, which estimates vaccination coverage for the 50 states. Compared with the baseline year of 1992, national coverage with 4 or more doses of DTP increased significantly, from 55% to 78%.

In comparison, some industrialized countries have much lower immunization levels. In a recent seroepidemiologic study from Spain, only 26% of the sample population of 3944 men and women aged 5 years to 59 years were fully protected and more than 85% of those aged 20 years to 39 years had little or no protection against diphtheria.[71] In other Western countries, serologic protection was found in 50% to 80% of subjects, with some countries showing a greater protection rate in older subjects (eg, Sweden) and some countries showing a greater protection rate in younger subjects (eg, Germany, France, Turkey, Slovakia).

Risks for travelers, therefore, are higher in parts of the world where immunization levels are low and the disease is prevalent. The Health Protection Agency Centre for Infections in the United Kingdom recommends boosters every 10 years for travelers planning to visit areas of endemic disease.[72] The CDC has an up-to-date Web site on diphtheria prevention for the public at www.cdc.gov/travel/diseases/dtp.htm

In 2008, the Advisory Committee on Immunization Practices (ACIP) issued guidelines on the prevention of pertussis, tetanus, and diphtheria in pregnant and postpartum women and their infants. In 2012, the American College of Obstetrics and Gynecology announced their findings that the toxoid in Tdap vaccine was not associated with adverse fetal outcomes and published their revised guidelines.[73]

Medication Summary

For C diphtheriae infection, the therapy is antitoxin and antibiotic treatment. Many antibiotics previously were effective, including penicillin, erythromycin, clindamycin, rifampin, and tetracycline. Resistance to penicillins, erythromycins, and clindamycin has been reported[43, 74] ; this is especially true for nontoxigenic C diphtheriae strains tested in Europe.[75]

For the nondiphtherial corynebacteria, antibiotic susceptibility testing often is required to determine the best treatment.

Booster treatment with diphtheria toxoid often is given. Please see Deterrence/Prevention for a discussion of vaccinations with toxoid.

Diphtheria antitoxin (DAT)

Clinical Context:  Dose given depends on site of infection and length of time patient is symptomatic. In US, DAT available from CDC. Contact diphtheria duty officer at 404-639-8255 from 8 AM to 4:30 PM (EST) or at 404-639-2889 all other times. Report all suspected cases of diphtheria to local and state health departments.

Class Summary

These agents are administered to neutralize toxin responsible for diphtheria.

Vancomycin (Vancocin)

Clinical Context:  Antibiotic useful against gram-positive organisms; corynebacteria are very often susceptible. Useful to treat septicemia, skin structure infections, and IV line infections/bacteremias.

Rifampin (Rifadin)

Clinical Context:  Nondiphtherial corynebacteria often are susceptible.

Linezolid (Zyvox)

Clinical Context:  Linezolid prevents formation of the functional 70S initiation complex, which is essential for the bacterial translation process. It is bacteriostatic against enterococci and staphylococci and bactericidal against most strains of streptococci. Corynebacteria are very often susceptible.[23] Linezolid is used as an alternative in patients allergic to vancomycin and for treatment of vancomycin-resistant enterococci.

Tetracycline (Sumycin, Actisite, Achromycin V)

Clinical Context:  Tetracycline treats gram-positive and gram-negative organisms as well as mycoplasmal, chlamydial, and rickettsial infections. Corynebacteria are often susceptible.[23] It inhibits bacterial protein synthesis by binding with 30S and possibly 50S ribosomal subunit(s).

Tigecycline (Tygacil)

Clinical Context:  Tigecycline is a glycylcycline antibiotic that is structurally similar to tetracycline antibiotics. It inhibits bacterial protein translation by binding to the 30S ribosomal subunit, and it blocks entry of amino-acyl tRNA molecules in ribosome A site.

It is indicated for complicated skin and skin structure infections caused by Escherichia coli, Enterococcus faecalis (vancomycin-susceptible isolates only), Staphylococcus aureus (methicillin-susceptible and methicillin-resistant isolates), Streptococcus agalactiae, Streptococcus anginosus grp (includes Streptococcus anginosus, Streptococcus intermedius, and Streptococcus constellatus), Streptococcus pyogenes, and Bacteroides fragilis. It is also generally effective against corynebacteria diphtheroids.[45]

Class Summary

Empiric antimicrobial therapy must be comprehensive and should cover all likely pathogens in the context of the clinical setting.  Prolonged therapy with multi-drug combinations may be necessary for infections with nondiphtherial corynebacteria. 

Clarithyromycin

Clinical Context:  Clarithryomycin belongs to the class of macrolide antibiotics, with a wide spectrum of activity against gram positive organisms - e.g., diphtheroids, staphylococcus, streptococcus - gram negative organisms, and anaerobic bacteria.

What are Corynebacterium infections?What is the pathophysiology of diphtherial Corynebacterium infections?What is the mode of transmission of diphtherial Corynebacterium infections?What is the pathophysiology of nondiphtherial Corynebacterium (diphtheroid) infections?What are the pathogenic groups of Corynebacterium infections?What is the prevalence of diphtherial Corynebacterium infections in the US?What is the prevalence of nondiphtherial Corynebacterium (diphtheroid) infections in the US?What is the global prevalence of diphtherial Corynebacterium infections?What is the global prevalence of nondiphtherial Corynebacterium (diphtheroid) infections?What is the mortality and morbidity associated with Corynebacterium infections?What are the racial predilections in the prevalence of Corynebacterium infections?What are the sexual predilections in prevalence of Corynebacterium infections?Which age groups have the highest incidence of Corynebacterium infections?What are the indications for vaccination against Corynebacterium infections?What are the signs and symptoms of diphtherial Corynebacterium infections?Which clinical history findings are characteristic of nondiphtherial Corynebacterium (diphtheroid) infections?Which respiratory exam findings are characteristic of diphtherial Corynebacterium infections?Which cardiac findings suggest diphtherial Corynebacterium infections?Which neurologic findings are characteristic of diphtherial Corynebacterium infections?Which dermatologic findings are characteristic of diphtherial Corynebacterium infections?Which physical findings are characteristic of nondiphtherial Corynebacterium (diphtheroid) infections?What are the differential diagnoses for Corynebacterium Infections?What is the role of lab testing in the workup of diphtherial Corynebacterium infections?What is the role of lab tests in the workup of nondiphtherial Corynebacterium (diphtheroid) infections?What is the role of electrocardiography in the workup of Corynebacterium infections?Which autopsy findings are characteristic of Corynebacterium infections?How are diphtherial Corynebacterium infections treated?How are nondiphtherial Corynebacterium (diphtheroid) infections treated?What is the role of surgery in the treatment of Corynebacterium infections?What resources are available from the CDC and WHO for the management of Corynebacterium infections?Which specialist consultations are beneficial in the treatment of Corynebacterium infections?How are Corynebacterium infections prevented?Which medications are used in the treatment of Corynebacterium infections?Which medications in the drug class Antibiotics are used in the treatment of Corynebacterium Infections?Which medications in the drug class Antitoxins are used in the treatment of Corynebacterium Infections?

Author

Lynda A Frassetto, MD, Clinical Professor, Department of Internal Medicine, University of California, San Francisco, School of Medicine

Disclosure: Nothing to disclose.

Specialty Editors

Francisco Talavera, PharmD, PhD, Adjunct Assistant Professor, University of Nebraska Medical Center College of Pharmacy; Editor-in-Chief, Medscape Drug Reference

Disclosure: Received salary from Medscape for employment. for: Medscape.

John W King, MD, Professor of Medicine, Chief, Section of Infectious Diseases, Director, Viral Therapeutics Clinics for Hepatitis, Louisiana State University School of Medicine in Shreveport; Consultant in Infectious Diseases, Overton Brooks Veterans Affairs Medical Center

Disclosure: Nothing to disclose.

Chief Editor

Pranatharthi Haran Chandrasekar, MBBS, MD, Professor, Chief of Infectious Disease, Department of Internal Medicine, Wayne State University School of Medicine

Disclosure: Nothing to disclose.

Additional Contributors

John M Leedom, MD, Professor Emeritus of Medicine, Keck School of Medicine of the University of Southern California

Disclosure: Nothing to disclose.

References

  1. Chaudhary A, Pandey S. Corynebacterium Diphtheriae. StatPearls. 2024 Jan. [View Abstract]
  2. Coyle MB, Lipsky BA. Coryneform bacteria in infectious diseases: clinical and laboratory aspects. Clin Microbiol Rev. 1990 Jul. 3(3):227-46. [View Abstract]
  3. Van den Velde S, Lagrou K, Desmet K, et al. Species identification of corynebacteria by cellular fatty acid analysis. Diagn Microbiol Infect Dis. 2006 Feb. 54(2):99-104. [View Abstract]
  4. Baumbach J. CoryneRegNet 4.0 - A reference database for corynebacterial gene regulatory networks. BMC Bioinformatics. 2007 Nov 6. 8:429. [View Abstract]
  5. Sharma NC, Banavaliker JN, Ranjan R, et al. Bacteriological & epidemiological characteristics of diphtheria cases in & around Delhi -a retrospective study. Indian J Med Res. 2007 Dec. 126(6):545-52. [View Abstract]
  6. Gaillet M, Hennart M, Rose VS, Badell E, Michaud C, Blaizot R, et al. Retrospective Study of Infections with Corynebacterium diphtheriae Species Complex, French Guiana, 2016-2021. Emerg Infect Dis. 2024 Aug. 30 (8):1545-1554. [View Abstract]
  7. Brockhaus L, Urwyler P, Leutwyler U, Würfel E, Kohns Vasconcelos M, Goldenberger D, et al. Diphtheria in a Swiss Asylum Seeker Reception Centre: Outbreak Investigation and Evaluation of Testing and Vaccination Strategies. Int J Public Health. 2024. 69:1606791. [View Abstract]
  8. Fraga MDSR, Angst FA, January J, Madziwa A, Gonah L, Lazzarotto A. The Burden and Risk Factors Associated with Infectious Diseases among Refugees in a Camp for Migrants in Porto Alegre: A Cross-Sectional Survey. Ann Glob Health. 2024. 90 (1):48. [View Abstract]
  9. Khan WJ, Khan Y, Alan S, Rahim S, Malik F. Diphtheria's disturbing comeback: An alarming resurgence in Pakistan. Journal of Pakistan Medical Association. 8/17/23. 1406.
  10. Rudresh SM, Ravi GS, Alex AM, Mamatha KR, Sunitha L, Ramya KT. Non Diphtheritic Corynebacteria: An Emerging Nosocomial Pathogen in Skin and Soft Tissue Infection. J Clin Diagn Res. 2015 Dec. 9 (12):DC19-21. [View Abstract]
  11. Dobinson HC, Anderson TP, Chambers ST, Doogue MP, Seaward L, Werno AM. Antimicrobial Treatment Options for Granulomatous Mastitis Caused by Corynebacterium Species. J Clin Microbiol. 2015 Sep. 53 (9):2895-9. [View Abstract]
  12. Joseph J, Nirmalkar K, Mathai A, Sharma S. Clinical features, microbiological profile and treatment outcome of patients with Corynebacterium endophthalmitis: review of a decade from a tertiary eye care centre in southern India. Br J Ophthalmol. 2016 Feb. 100 (2):189-94. [View Abstract]
  13. Williams MS, McClintock AH, Bourassa L, Laya MB. Treatment of Granulomatous Mastitis: Is There a Role for Antibiotics?. Eur J Breast Health. 2021 Jul. 17 (3):239-246. [View Abstract]
  14. Bnaya A, Wiener-Well Y, Soetendorp H, Einbinder Y, Paitan Y, Kunin M, et al. Nontuberculous mycobacteria infections of peritoneal dialysis patients: A multicenter study. Perit Dial Int. 2021 May. 41 (3):284-291. [View Abstract]
  15. Nasim F, Dey A, Qureshi IA. Comparative genome analysis of Corynebacterium species: The underestimated pathogens with high virulence potential. Infect Genet Evol. 2021 Sep. 93:104928. [View Abstract]
  16. Datta P, Gupta V, Gupta M, Pal K, Chander J. Corynebacterium Striatum, an Emerging Nosocomial Pathogen: Case Reports. Infect Disord Drug Targets. 2021. 21 (2):301-303. [View Abstract]
  17. Shariff M, Aditi A, Beri K. Corynebacterium striatum: an emerging respiratory pathogen. J Infect Dev Ctries. 2018 Jul 31. 12 (7):581-586. [View Abstract]
  18. Rezaei Bookani K, Marcus R, Cheikh E, Parish M, Salahuddin U. Corynebacterium jeikeium endocarditis: A case report and comprehensive review of an underestimated infection. IDCases. 2018. 11:26-30. [View Abstract]
  19. Shanbhag SS, Shih G, Bispo PJM, Chodosh J, Jacobs DS, Saeed HN. Diphtheroids as Corneal Pathogens in Chronic Ocular Surface Disease in Stevens-Johnson Syndrome/Toxic Epidermal Necrolysis. Cornea. 2021 Jun 1. 40 (6):774-779. [View Abstract]
  20. Baird GJ, Fontaine MC. Corynebacterium pseudotuberculosis and its role in ovine caseous lymphadenitis. J Comp Pathol. 2007 Nov. 137(4):179-210. [View Abstract]
  21. Yeruham I, Elad D, Avidar Y, et al. A herd level analysis of urinary tract infection in dairy cattle. Vet J. 2006 Jan. 171(1):172-6. [View Abstract]
  22. Rogers EA, Das A, Ton-That H. Adhesion by pathogenic corynebacteria. Adv Exp Med Biol. 2011. 715:91-103. [View Abstract]
  23. Moreira Lde O, Andrade AF, Vale MD, et al. Effects of iron limitation on adherence and cell surface carbohydrates of Corynebacterium diphtheriae strains. Appl Environ Microbiol. 2003 Oct. 69(10):5907-13. [View Abstract]
  24. Mandlik A, Swierczynski A, Das A, et al. Corynebacterium diphtheriae employs specific minor pilins to target human pharyngeal epithelial cells. Mol Microbiol. 2007 Apr. 64(1):111-24. [View Abstract]
  25. Mel'nikov VG, Kombarova SIu, Borisova OIu, et al. [Corynebacterium diphtheriae nontoxigenic strain carrying the gene of diphtheria toxin]. Zh Mikrobiol Epidemiol Immunobiol. 2004 Jan-Feb. 3-7. [View Abstract]
  26. De Zoysa A, Efstratiou A, Hawkey PM. Molecular characterization of diphtheria toxin repressor (dtxR) genes present in nontoxigenic Corynebacterium diphtheriae strains isolated in the United Kingdom. J Clin Microbiol. 2005 Jan. 43(1):223-8. [View Abstract]
  27. Bernard K. The genus corynebacterium and other medically relevant coryneform-like bacteria. J Clin Microbiol. 2012 Oct. 50 (10):3152-8. [View Abstract]
  28. Nasim F, Dey A, Qureshi IA. Comparative genome analysis of Corynebacterium species: The underestimated pathogens with high virulence potential. Infect Genet Evol. 2021 Sep. 93:104928. [View Abstract]
  29. Moazzez A, Kelso RL, Towfigh S, Sohn H, Berne TV, Mason RJ. Breast abscess bacteriologic features in the era of community-acquired methicillin-resistant Staphylococcus aureus epidemics. Arch Surg. 2007 Sep. 142(9):881-4. [View Abstract]
  30. Efstratiou A, Engler KH, Mazurova IK, et al. Current approaches to the laboratory diagnosis of diphtheria. J Infect Dis. 2000 Feb. 181 Suppl 1:S138-45. [View Abstract]
  31. Kadirova R, Kartoglu HU, Strebel PM. Clinical characteristics and management of 676 hospitalized diphtheria cases, Kyrgyz Republic, 1995. J Infect Dis. 2000 Feb. 181 Suppl 1:S110-5. [View Abstract]
  32. Quick ML, Sutter RW, Kobaidze K, et al. Epidemic diphtheria in the Republic of Georgia, 1993-1996: risk factors for fatal outcome among hospitalized patients. J Infect Dis. 2000 Feb. 181 Suppl 1:S130-7. [View Abstract]
  33. Wagner KS, White JM, Neal S, Crowcroft NS, Kupreviciene N, Paberza R, et al. Screening for Corynebacterium diphtheriae and Corynebacterium ulcerans in patients with upper respiratory tract infections 2007-2008: a multicentre European study. Clin Microbiol Infect. 2011 Apr. 17(4):519-25. [View Abstract]
  34. Wren MW, Shetty N. Infections with Corynebacterium diphtheriae: six years' experience at an inner London teaching hospital. Br J Biomed Sci. 2005. 62(1):1-4. [View Abstract]
  35. Mattos-Guaraldi AL, Moreira LO, Damasco PV, et al. Diphtheria remains a threat to health in the developing world--an overview. Mem Inst Oswaldo Cruz. 2003 Dec. 98(8):987-93. [View Abstract]
  36. Webb R, Voss L, Roberts S, Hornung T, Rumball E, Lennon D. Infective endocarditis in new zealand children 1994-2012. Pediatr Infect Dis J. 2014 May. 33(5):437-42. [View Abstract]
  37. Zakikhany K, Efstratiou A. Diphtheria in Europe: current problems and new challenges. Future Microbiol. 2012 May. 7(5):595-607. [View Abstract]
  38. Yang K, Kruse RL, Lin WV, Musher DM. Corynebacteria as a cause of pulmonary infection: a case series and literature review. Pneumonia (Nathan). 2018. 10:10. [View Abstract]
  39. Egwari LO, Nwokoye NN, Obisesan B, Coker AO, Nwaokorie FO, Savage KO. Bacteriological and clinical evaluation of twelve cases of post-surgical sepsis of odontogenic tumours at a referral centre. East Afr Med J. 2008 Jun. 85(6):269-74. [View Abstract]
  40. Wagner KS, White JM, Crowcroft NS, De Martin S, Mann G, Efstratiou A. Diphtheria in the United Kingdom, 1986-2008: the increasing role of Corynebacterium ulcerans. Epidemiol Infect. 2010 Nov. 138(11):1519-30. [View Abstract]
  41. Dias AA, Santos LS, Sabbadini PS, Santos CS, Silva Junior FC, Napoleão F, et al. Corynebacterium ulcerans diphtheria: an emerging zoonosis in Brazil and worldwide. Rev Saude Publica. 2011 Dec. 45(6):1176-91. [View Abstract]
  42. Tarr PE, Stock F, Cooke RH, Fedorko DP, Lucey DR. Multidrug-resistant Corynebacterium striatum pneumonia in a heart transplant recipient. Transpl Infect Dis. 2003 Mar. 5(1):53-8. [View Abstract]
  43. Ghide S, Jiang Y, Hachem R, Chaftari AM, Raad I. Catheter-related Corynebacterium bacteremia: should the catheter be removed and vancomycin administered?. Eur J Clin Microbiol Infect Dis. 2010 Feb. 29(2):153-6. [View Abstract]
  44. Hernandez NM, Buchanan MW, Cullen MM, Crook BS, Bolognesi MP, Seidelman J, et al. Corynebacterium Total Hip and Knee Arthroplasy Prosthetic Joint Infections. Arthroplast Today. 2020 Jun. 6 (2):163-168. [View Abstract]
  45. Sattar A, Yu S, Koirala J. Corynebacterium CDC Group G Native and Prosthetic Valve Endocarditis. Infect Dis Rep. 2015 Aug 11. 7 (3):5881. [View Abstract]
  46. Chatzopoulou M, Koufakis T, Voulgaridi I, Gabranis I, Tsiakalou M. A case of fatal sepsis due to multidrug-resistant Corynebacterium striatum. Hippokratia. 2016 Jan-Mar. 20 (1):67-69. [View Abstract]
  47. Harnisch JP, Tronca E, Nolan CM, et al. Diphtheria among alcoholic urban adults. A decade of experience in Seattle. Ann Intern Med. 1989 Jul 1. 111(1):71-82. [View Abstract]
  48. Datta P, Gupta V, Gupta M, Pal K, Chander J. Corynebacterium Striatum, an Emerging Nosocomial Pathogen: Case Reports. Infect Disord Drug Targets. 2021. 21 (2):301-303. [View Abstract]
  49. Cappuccino L, Bottino P, Torricella A, Pontremoli R. Nephrolithiasis by Corynebacterium urealyticum infection: literature review and case report. J Nephrol. 2014 Apr. 27(2):117-25. [View Abstract]
  50. From the Centers for Disease Control and Prevention. Respiratory diphtheria caused by Corynebacterium ulcerans--Terre Haute, Indiana, 1996. JAMA. 1997 Jun 4. 277(21):1665-6. [View Abstract]
  51. Dewinter LM, Bernard KA, Romney MG. Human clinical isolates of Corynebacterium diphtheriae and Corynebacterium ulcerans collected in Canada from 1999 to 2003 but not fitting reporting criteria for cases of diphtheria. J Clin Microbiol. 2005 Jul. 43(7):3447-9. [View Abstract]
  52. Lee PP, Ferguson DA Jr, Sarubbi FA. Corynebacterium striatum: an underappreciated community and nosocomial pathogen. J Infect. 2005 May. 50(4):338-43. [View Abstract]
  53. Manzella JP, Kellogg JA, Parsey KS. Corynebacterium pseudodiphtheriticum: a respiratory tract pathogen in adults. Clin Infect Dis. 1995 Jan. 20(1):37-40. [View Abstract]
  54. Camello TC, Souza MC, Martins CA, Damasco PV, Marques EA, Pimenta FP, et al. Corynebacterium pseudodiphtheriticum isolated from relevant clinical sites of infection: a human pathogen overlooked in emerging countries. Lett Appl Microbiol. 2009 Apr. 48(4):458-64. [View Abstract]
  55. Turk S, Korrovits P, Punab M, et al. Coryneform bacteria in semen of chronic prostatitis patients. Int J Androl. 2007 Apr. 30(2):123-8. [View Abstract]
  56. Ivanov IB, Kuzmin MD, Gritsenko VA. Microflora of the seminal fluid of healthy men and men suffering from chronic prostatitis syndrome. Int J Androl. 2009 Oct. 32(5):462-7. [View Abstract]
  57. Mathelin C, Riegel P, Chenard MP, Tomasetto C, Brettes JP. Granulomatous mastitis and corynebacteria: clinical and pathologic correlations. Breast J. 2005 Sep-Oct. 11(5):357. [View Abstract]
  58. Suzuki T, Iihara H, Uno T, et al. Suture-related keratitis caused by Corynebacterium macginleyi. J Clin Microbiol. 2007 Nov. 45(11):3833-6. [View Abstract]
  59. Otsuka Y, Kawamura Y, Koyama T, et al. Corynebacterium resistens sp. nov., a new multidrug-resistant coryneform bacterium isolated from human infections. J Clin Microbiol. 2005 Aug. 43(8):3713-7. [View Abstract]
  60. Mokrousov I. Corynebacterium diphtheriae: genome diversity, population structure and genotyping perspectives. Infect Genet Evol. 2009 Jan. 9(1):1-15. [View Abstract]
  61. [Guideline] Bernard K. The genus corynebacterium and other medically relevant coryneform-like bacteria. J Clin Microbiol. 2012 Oct. 50(10):3152-8. [View Abstract]
  62. Torres Lde F, Ribeiro D, Hirata Jr R, Pacheco LG, Souza MC, dos Santos LS, et al. Multiplex polymerase chain reaction to identify and determine the toxigenicity of Corynebacterium spp with zoonotic potential and an overview of human and animal infections. Mem Inst Oswaldo Cruz. 2013 May. 108(3):[View Abstract]
  63. Rajamani Sekar SK, Veeraraghavan B, Anandan S, Devanga Ragupathi NK, Sangal L, Joshi S. Strengthening the laboratory diagnosis of pathogenic Corynebacterium species in the Vaccine era. Lett Appl Microbiol. 2017 Nov. 65 (5):354-365. [View Abstract]
  64. Hennart M, Panunzi LG, Rodrigues C, Gaday Q, Baines SL, Barros-Pinkelnig M, et al. Population genomics and antimicrobial resistance in Corynebacterium diphtheriae. Genome Med. 2020 Nov 27. 12 (1):107. [View Abstract]
  65. Yamamuro R, Hosokawa N, Otsuka Y, et al. Clinical Characteristics of Corynebacterium Bacteremia Caused by Different Species, Japan, 2014–2020. Emerging Infectious Diseases. 2021. 27(12):2981-2987.
  66. Riegel P, Ruimy R, Christen R, et al. Species identities and antimicrobial susceptibilities of corynebacteria isolated from various clinical sources. Eur J Clin Microbiol Infect Dis. 1996 Aug. 15(8):657-62. [View Abstract]
  67. Spanik S, Trupl J, Kunova A, et al. Risk factors, aetiology, therapy and outcome in 123 episodes of breakthrough bacteraemia and fungaemia during antimicrobial prophylaxis and therapy in cancer patients. J Med Microbiol. 1997 Jun. 46(6):517-23. [View Abstract]
  68. Join-Lambert OF, Ouache M, Canioni D, et al. Corynebacterium pseudotuberculosis necrotizing lymphadenitis in a twelve-year-old patient. Pediatr Infect Dis J. 2006 Sep. 25(9):848-51. [View Abstract]
  69. [Guideline] World Health Organization. Diphtheria. WHO. Available at https://www.who.int/news-room/fact-sheets/detail/diphtheria#:~:text=Key%20facts,to%20produce%20and%20sustain%20immunity.. July 12, 2024; Accessed: August 17, 2024.
  70. McCormack PL. Reduced-antigen, combined diphtheria, tetanus and acellular pertussis vaccine, adsorbed (Boostrix®): a review of its properties and use as a single-dose booster immunization. Drugs. 2012 Sep 10. 72(13):1765-91. [View Abstract]
  71. Garcia-Corbeira P, Dal-Re R, Garcia-de-Lomas J, et al. Low prevalence of diphtheria immunity in the Spanish population: results of a cross-sectional study. Vaccine. 1999 Apr 9. 17(15-16):1978-82. [View Abstract]
  72. Cameron C, White J, Power D, et al. Diphtheria boosters for adults: balancing risks. Travel Med Infect Dis. 2007 Jan. 5(1):35-9. [View Abstract]
  73. Committee opinion no. 521: update on immunization and pregnancy: tetanus, diphtheria, and pertussis vaccination. Obstet Gynecol. 2012 Mar. 119(3):690-1. [View Abstract]
  74. Reddy BS, Chaudhury A, Kalawat U, Jayaprada R, Reddy G, Ramana BV. Isolation, speciation, and antibiogram of clinically relevant non-diphtherial Corynebacteria (Diphtheroids). Indian J Med Microbiol. 2012 Jan. 30(1):52-7. [View Abstract]
  75. von Hunolstein C, Scopetti F, Efstratiou A, et al. Penicillin tolerance amongst non-toxigenic Corynebacterium diphtheriae isolated from cases of pharyngitis. J Antimicrob Chemother. 2002 Jul. 50(1):125-8. [View Abstract]
  76. Neuweger H, Baumbach J, Albaum S, et al. CoryneCenter - an online resource for the integrated analysis of corynebacterial genome and transcriptome data. BMC Syst Biol. 2007 Nov 22. 1:55. [View Abstract]

The corynebacterial tox gene is regulated by the corynebacterial iron-binding repressor, labeled DtxR. Binding of ferrous iron to the DtxR molecule forms a complex that binds to the tox gene operator and inhibits transcription. Depletion of iron from the system removes the repression and allows the toxin to be produced.

The characteristic thick membrane of diphtheria infection in the posterior pharynx.

Cervical edema and cervical lymphadenopathy from diphtheria infection produce a bullneck appearance in this child. Courtesy of Immunize.org, formerly Immunization Action Coalition (IAC) [https://www.immunize.org/].

The corynebacterial tox gene is regulated by the corynebacterial iron-binding repressor, labeled DtxR. Binding of ferrous iron to the DtxR molecule forms a complex that binds to the tox gene operator and inhibits transcription. Depletion of iron from the system removes the repression and allows the toxin to be produced.

The characteristic thick membrane of diphtheria infection in the posterior pharynx.

Cervical edema and cervical lymphadenopathy from diphtheria infection produce a bullneck appearance in this child. Courtesy of Immunize.org, formerly Immunization Action Coalition (IAC) [https://www.immunize.org/].

Final case classification of corynebacteria infections. Courtesy of the World Health Organization (WHO) [Surveillance standards for vaccine-preventable diseases, 2nd ed, 2018, https://apps.who.int/iris/handle/10665/275754].