Anaplasma marginale
A Microbial Biorealm page on the genus Anaplasma marginale
Classification
Higher order taxa
Bacteria; Proteobacteria; Alphaproteobacteria; Rickettsiales; Anaplasmataceae
Species
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NCBI: Taxonomy |
Anaplasma marginale
Strains:
Anaplasma marginale str. Florida; Anaplasma marginale str. Illinois; Anaplasma marginale str. St. Maries; Anaplasma marginale str. Virginia
Other names:
Anaplasma theileri; Anaplasma rossicum; Anaplasma argentium; Anaplasma theileri Neitz 1957; Anaplasma rossicum Yakimoff and Belawine 1927; Anaplasma argentium Lignieres 1914; Anaplasma marginale Theiler 1910
Description and significance
Genome structure
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Genome: Genome |
Genome Info: Features: BLAST homologs: Links: Review Info: Refseq: NC_004842 Genes: 1005 COG Genome Project Publications: [1] GenBank: CP000030 Protein coding: 949 3D Structure Refseq FTP Refseq Status: Provisional Length: 1,197,687 nt Structural RNAs: 40 TaxMap GenBank FTP Seq.Status: Completed GC Content: 49% Pseudo genes: 16 TaxPlot BLAST Sequencing center: Washington State University % Coding: 85% Others: None GenePlot TraceAssembly Completed: 2003/06/17 Topology: circular Contigs: 1 gMap CDD Organism Group Molecule: DNA Other genomes for species
Cell structure and metabolism
Anaplasma Marginale is a pathogenic gram-negative stain bacteria with an outer membrane composed of lipopolysaccharides. (info about gram-negative bacteria) Its class, Alphaproteobacteria (particularly the order Rickettsiales), are thought to be the precursors of the mitochondria of eukaryotic cells. According to the endosymbiotic theory, the mitochondria organelle now existant in eukaryotic cells originated as separate prokaryotic organisms which were taken inside the cell as endosymbionts.
Ecology
Specific species of cattle ticks are carriers of Anaplasma marginale The organism multiplies in the tick and will pass to later stages of the tick life cycle. However, it does not appear the infection is passed on to the eggs. Consequently, the next generation of ticks will not be infected unless they also feed on a carrier animal. As carriers, they are unaffected by the bacteria. These ticks carry this infection and infect cattle as a parasite feeding off the bood of the host. Because the adult male tick is more mobile and lives longer than other stages, it is the most likely stage to transmit the disease. Biting flies can transmit the disease but are less efficient vectors than ticks. The organism can also cross the placenta to the fetus.
Calves from immune mothers receive temporary protection (maternal antibody) from the colostrum (first milk) which prevents anaplasmosis. This protection lasts about 3 months and, in most cases, is followed by an age resistance that lasts until the animals are about 9 to 12 months old. Calves exposed to anaplasmosis when the maternal or age resistance is high, rarely show clinical symptoms but develop a solid, long lasting immunity. It is therefore possible to have both Anaplasma marginale and cattle ticks present on a property without animal losses or clinical disease. If cattle are not exposed to Anaplasma as calves, the age resistance gradually wanes and these animals will become increasingly susceptible to the disease. If susceptible adult cattle are mixed with infected cattle in the presence of the cattle tick, serious losses due to anaplasmosis can occur.
Pathology
Anaplasmosis is a form of tick fever carried by a specfic species of cattle tick. As the disease progresses, infected and even uninfected red blood cells are destroyed mainly in the liver and spleen, resulting in an increasing anaemia and even death in severe cases. Any stage of the cattle tick’s life cycle can become infected after feeding on an animal carrying Anaplasma organisms in its blood stream. Therefore an infected stage of the tick must transfer to a susceptible animal for transmission to occur. The bacteria begins its course by invading and multiplying in red blood cells of the host cattle.
Clinical symptoms of infection include transient fever, weakness and respiratory distress particularly after exercise, depression and loss of appetite, jaundice, and brown urine due to bile pigments. Cattle that recover from anaplasmosis remain carriers of the organism and are immune to further disease.
Application to Biotechnology
Does this organism produce any useful compounds or enzymes? What are they and how are they used?
Current Research
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References
NCBI Taxonomy Browser, "Anaplasma marginale" Retrieved 30 April, 2007
HealthGene - Molecular Diagnostic and Research Center. "D425 Anaplasma Marginale"
National Institute of Health, "Anaplasma Marginale" Retrieved 30 April, 2007
Edited by Patricia Shih; student of Rachel Larsen and Kit Pogliano
