incidents attributed to cyanobacter

incidents attributed to cyanobacterial toxins are generally thought
to be rare and the incidence of mortality is generally less than for
animal species affected by cyanobacterial toxins. However, human
deaths have occurred, most notably at a hemodialysis clinic at
Caruaru, Brazil, where inadequately treated water containing cyanobacterial
toxins, was the cause of patient mortality and illness
(Carmichael et al., 2001; Codd et al., 1999).
The toxic compounds produced by cyanobacteria have a variety
of structures, modes of action and effects in mammalian systems.
The most commonly reported cyanobacterial toxins are the cyclic
peptide hepatotoxins; the microcystins and nodularins. The seven
(microcystins) and five (nodularins) amino acid cyclic compounds
are potent inhibitors of protein phosphatases and phosphoprotein
phosphatases (Hastie et al., 2005). In large enough doses, death can
occur by hypovolemic shock due to the destruction of the liver, and
in combination with tumour initiators, microcystins may act as
tumour promoters. Other hepatotoxic compounds include the
cylindrospermopsins, cyclic guanidine alkaloids which have been
shown to be produced by cyanobacterial genera including Cylindrospermopsis,
Anabaena and Aphanizomenon. They act by inhibiting
protein translation as demonstrated in the rabbit reticulocyte
lysate assay (Froscio et al., 2001), and are also considered to be
carcinogenic (Humpage, 2008). Other alkaloid toxins produced by
cyanobacteria include the anatoxins, anatoxin-a and anatoxin-a(S).
Anatoxin-a is a highly toxic compound which acts as an acetylcholine
mimic, causing death by paralysis at high enough doses and
is commonly found to be produced by Phormidium species. Anatoxin-
a(S) although with a similar name, can be produced by Anabaena
and has a completely different mode of action. The structure
and action is that of an organophosphate, similar to organophosphorus
pesticides, which inhibit acetylcholine esterases resulting in
paralysis and death at sufficient concentration (Metcalf and Codd,
2012).
Cyanobacteria have also been shown to be capable of producing
saxitoxins, common shellfish poisoning toxins associated with
marine dinoflagellate blooms and contaminated shellfish
(Llewellyn, 2009). Saxitoxins are extremely potent natural products,
with their major mode of action acting through the inhibition
of sodium channels. In high enough doses, death can occur in minutes
due to paralysis and respiratory arrest (Metcalf and Codd,
2012).
Although a large number of cyanotoxins are known for their
rapid and acute toxicity, neurotoxic amino acids, shown to be
produced by cyanobacteria, have gained interest due to their
connection to long-term human neurodegenerative diseases (Cox