Brucella is a genus of Gram-negative bacteria, named after David Bruce (1855–1931). They are small (0.5 to 0.7 by 0.6 to 1.5 μm), non-encapsulated, non-motile, facultatively intracellular coccobacilli.

Brucella spp. are the cause of brucellosis, which is a zoonosis transmitted by ingesting contaminated food (such as unpasteurized milk products), direct contact with an infected animal, or inhalation of aerosols. Transmission from human to human, for example, through sexual intercourse, or from mother to child, is exceedingly rare, but possible. Minimum infectious exposure is between 10 and 100 organisms.

The different species of Brucella are genetically very similar, although each has a slightly different host specificity. Hence, the National Center for Biotechnology Information taxonomy includes most Brucella species under B. melitensis.

The many names of brucellosis include (human disease/animal disease):

  • Malta fever/Bang's disease
  • Undulant fever/enzootic abortion
  • Mediterranean fever/epizootic abortion
  • Rock fever of Gibraltar/slinking of calves
  • Gastric fever/ram epididymitis
  • Contagious abortion/spontaneous abortion

Human brucellosis

Sir David Bruce isolated B. melitensis from British soldiers who died from Malta fever in Malta. After exposure to Brucella, humans generally have a two- to four-week latency period before exhibiting symptoms, which include acute undulating fever (>90% of all cases), headache, arthralgia (>50%), night sweats, fatigue, and anorexia. Later complications may include arthritis or epididymo-orchitis, spondylitis, neurobrucellosis, liver abscess formation, and endocarditis, the latter potentially fatal.

Human brucellosis is usually not transmitted from human to human; people become infected by contact with fluids from infected animals (sheep, cattle, or pigs) or derived food products, such as unpasteurized milk and cheese. Brucellosis is also considered an occupational disease because of a higher incidence in people working with animals (slaughterhouse cases). People may also be infected by inhalation of contaminated dust or aerosols, and as such, the CDC has labeled Brucella species as highly weaponizable.

Human and animal brucellosis share the persistence of the bacteria in tissues of the mononuclear phagocyte system, including the spleen, liver, lymph nodes, and bone marrow. Brucella can also target the male reproductive tract. In 1860, J.A. Maraston, assistant surgeon in the British Army in Malta, gave the first accurate description of the disease he called "Mediterranean gastric remittent fever".

In 1897, A.E. Wright, a pathologist in British army, developed the agglutination test, diagnostic of the disease.

In 1905, Zammit, a Maltese physician, identified goats as the source of infection. E. Bang, a Danish veterinarian, described the intracellular pathogen causing abortion in cattle in 1897, and named it Bacillus abortus. In 1918, A. Evans, an American microbiologist, made the connection between B. abortus and Micrococcus melitensis, and placed them in the Bacteriaceae.

In 1914, Mohler isolated an organism from the liver and spleen of pigs, B. suis; B. neotome, B. ovis, and B. canis were described in 1957, 1963, and 1966, respectively. In humans, the disease is acquired from unpasteurised milk and products or undercooked meat (consumers), laboratory inhalation (lab workers), accidental skin penetration or abrasion (farmers, slaughterhouse workers, and veterinarians), and (rarely) conjunctival contact, blood transfusion, transplacental, and person-to-person.

Human disease

Brucellosis can affect any organ or organ system, and 90% of patients have a cyclical (undulant) fever. Though variable, symptoms can also include these clinical signs: headache, weakness, arthralgia, depression, weight loss, fatigue, and liver dysfunction. Foul-smelling perspiration is considered a classical sign. Between 20 and 60% of cases have osteoarticular complications: arthritis, spondylitis, or osteomyelitis. Hepatomegaly may occur, as can gastrointestinal complications.

Up to 20% of cases can have genitourinary involvement; orchitis and epididymitis are most common. Neurological symptoms include depression and mental fatigue. Cardiovascular involvement can include endocarditis resulting in death.

Chronic brucellosis is hard to define; length, type, and response to treatment are variable. Localized infection can occur. Blood donations of infected persons should not be accepted. Congenitally infected infants can exhibit low birth weight, failure to thrive, jaundice, hepatomegaly, splenomegaly, respiratory difficulty, and general signs of sepsis (fever, vomiting). Some cases are asymptomatic.

Characteristics

Brucella species are small, Gram-negative, facultative coccobacilli, most lacking a capsule, endospores, or native plasmids. They are intracellular within the host organism, and show environmental persistence outside the host. The intracellular trafficking includes two or three main steps, starting with endosomal vacuoles, then endoplasmic reticulum-derived compartments and finally vacuoles having several markers of atypical autophagy. They survive extremes in temperature, pH, and humidity, and in frozen and aborted materials. They infect many species, but with some specificity.

The Brucella species belongs to the Rhizobiales group, in the Alphaproteobacteria class. They are growing by unipolar growth, like Agrobacterium tumefaciens, Sinorhizobium meliloti, and Ochrobactrum anthropi. They usually have two chromosomes

Clinical manifestations

The gastrointestinal tract is affected in about 70% of cases, including anorexia, abdominal pain, vomiting, diarrhea, constipation, hepatomegaly, and splenomegaly. The liver is involved in most cases, but function tests are normal or mildly abnormal. Granulomas (B. abortus), hepatitis (B. melitensis), and abscesses (B. suis) are seen.

The skeletal system is affected in 20–60% of cases, including arthritis (hip, knee, and ankle), spondylitis, osteomyelitis, and sacroiliitis (most common). Lumbar vertebrae can be affected showing the classical radiological sign of vertebral erosion. <!-- (Pedro Pons sign) --> Neurological symptoms include meningitis, encephalitis, radiculopathy, peripheral neuropathy, intracerebral abscesses, and acute or chronic neck rigidity (<50%), and the cerebrospinal fluid can show lymphocytic pleocytosis, low sugar, increased protein, positive bacterial culture (<50%), and agglutination (positive in >95%).

Cardiovascular involvement is low (endocarditis at 2%), but is the major cause of mortality. Often, valve replacement and antibiotics are needed. Pericarditis and myocarditis are seen, too.

Pulmonary infection can be from inhalation or hematogenous sources, and can cause any chest syndrome. Rarely is Brucella isolated from sputum. Genitourinary infection can include epidydemoorchitis or pyonephrosis (rare). Cutaneous involvement is not specific. Hematological signs include anemia, leukopenia, and thrombocytopenia.

Diagnosis

Brucella is isolated from a blood culture on Castaneda medium or from bone marrow. Prolonged incubation (up to six weeks) may be required, as they are slow-growing, but on modern automated machines, the cultures often show positive results within 7 days. On Gram stain, they appear as dense clumps of Gram-negative coccobacilli and are exceedingly difficult to see. In recent years, molecular diagnostic techniques based on the genetic component of the pathogen have become more popular. This most often happens when the disease is not thought of until cultures become positive, by which time the specimens have already been handled by a number of laboratory staff. The idea of preventive treatment is to stop people who have been exposed to Brucella from becoming ill with the disease.

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Isolation of organism

Blood, bone marrow, other tissues

Serum agglutination test

Four-fold or greater rise in titer

Samples 2 weeks apart

Immunofluorescence

Organism in clinical specimens

PCR -->

Polymerase chain reaction (PCR) shows promise for rapid diagnosis of Brucella species in human blood specimens. Positive PCR at the completion of treatment is not predictive of subsequent relapse. PCR testing for fluid and tissue samples other than blood has also been described. A history of animal contact is pivotal; in endemic area, it should be in the diagnosis of any nonspecific febrile illness.

In the laboratory, biochemical tests can be diagnostic. The sensitivity of the ELISA was 100% when compared with blood culture, but only 44% compared with serologic tests other than ELISA. The specificity was >99%. In a study including 75 patients with brucellosis, five patients with positive ELISA had a negative tube agglutination test. In several Brucella-endemic regions, the Febrile Antigen Brucella Agglutination Test (FBAT) is primarily used for diagnostics. Recent investigations on the use of FBAT have however illustrated its high inaccuracy in proper diagnosis, highlighting the difficulty of brucellosis control in low-income settings.

In the setting of Brucella arthritis, the synovial-fluid white blood cell count does not generally exceed 15,000 cells/μl. for brucellosis before the use of antibiotics had a mortality of 2%, mainly due to endocarditis, and morbidity was high, especially with B. melitensis. Permanent nerve deafness and spinal cord damage often occurred.

Prevention the advantage of this regimen is that it is oral medication with no injections; however, a high rate of side effects (nausea, vomiting, loss of appetite) has also been reported.

Host specificity and animal brucellosis

Brucella species have been found primarily in mammals: Drugs with effects against Brucella include tetracyclines, aminoglycosides (streptomycin, [since 1947], gentamicin, netilmicin), rifampicin, quinolones (ciprofloxacin), and third-generation cephalosporins. Treatment for uncomplicated brucellosis includes:

  • Streptomycin + doxycycline for 6 weeks
  • TMP/SMX + doxycycline for 6 weeks
  • Rifampicin + doxycycline for 6 weeks

Treatment of complicated brucellosis (endocarditis, meningitis) has no uniform agreement, but usually uses three anti-Brucella drugs for three months.

The plague of Thebes

<!-- According to an article in Emerging Infectious Diseases, -->Brucellosis caused by B. abortus best fits the characteristics of the plague described in Oedipus Rex. Although the disease progression of brucellosis in modern times may make it seem unlikely, <!-- the authors posit that --> it was at least one agent in what may have been a multicomponent plague, along with Salmonella enterica serovar Typhi or another pathogen, or possibly the ancestral versions of Brucella were more lethal.

Genomics

The Brucella genome includes two chromosomes; the first chromosome codes mostly for genes related to metabolism, while the second (smaller one) includes several genes related to pathogenicity. The genomes of most Brucella species have been sequenced, and typically encode 3,200 to 3,500 open reading frames (ORFs). Examples include:

  1. Brucella abortus A13334, 3,401 ORFs
  2. Brucella canis ATCC 23365, 3,408 ORFs
  3. Brucella melitensis 16M, 3,279 ORFs
  4. Brucella microti CCM 4915, 3,346 ORFs
  5. Brucella ovis ATCC 25840, 3,193 ORFs
  6. Brucella pinnipedialis B2/94, 3,505 ORFs
  7. Brucella suis 1330, 3,408 ORFs

Genome data for these and other Brucella strains are available in the GOLD databases. Also, a public and editable spreadsheet of B. abortus 2308W genome annotation has been created, to be updated based on new discoveries. Also, the genome annotation is available in a user friendly table at the web page http://hdl.handle.net/11056/23125.

Bacterial small RNAs (sRNA) are an important class of regulatory molecules. Many Brucella sRNAs have been identified.

Phylogeny

The currently accepted taxonomy is based on the List of Prokaryotic names with Standing in Nomenclature (LPSN).

Effect of blue light

Infection of macrophages by B. abortus is stimulated by blue light in the wild type, but is limited in photochemically inactive and null mutants, indicating a flavin-containing histidine kinase functions as a photoreceptor regulating B. abortus virulence. Conversely, depriving Brucella of the blue wavelengths dropped its reproductive rate by 90%.

Notes

References

  • Brucella genomes and related information at PATRIC, a Bioinformatics Resource Center funded by NIAID
  • Brucella Genome Projects (from Genomes OnLine Database)
  • Comparative Analysis of Brucella Genomes (at DOE's IMG system)
  • Brucella Bioinformatics Portal
  • Brucellosis subject guide of the University of Navarra