Synaptic changes in frontotemporal lobar degeneration: correlation with MAPT haplotype and APOE genotype.

AIMS: This immunohistochemical study quantified synaptic changes (synaptophysin and SNAP-25) in the frontal lobe of subjects with frontotemporal lobar degeneration (FTLD) and Alzheimer's disease (AD), and related these to APOE genotype and MAPT haplotype. METHODS: Frontal neocortex (BA9) of post mortem brains from subjects with FTLD (n = 20), AD (n = 10) and age-matched controls (n = 9) were studied immunohistochemically for synaptophysin and SNAP-25. RESULTS: We report that patients with FTLD have a significant increase in synaptophysin and depletion in SNAP-25 proteins compared to both control subjects and individuals with AD (P < 0.001). The FTLD up-regulation of synaptophysin is disease specific (P < 0.0001), and is not influenced by age (P = 0.787) or cortical atrophy (P = 0.248). The SNAP-25 depletion is influenced by a number of factors, including family history and histological characteristics of FTLD, APOE genotype, MAPT haplotype and gender. Thus, more profound loss of SNAP-25 occurred in tau-negative FTLD, and was associated with female gender and lack of family history of FTLD. Presence of APOEε4 allele and MAPT H2 haplotype in FTLD had a significant influence on the expression of synaptic proteins, specifically invoking a decrease in SNAP-25. CONCLUSIONS: Our results suggest that synaptic expression in FTLD is influenced by a number of genetic factors which need to be taken into account in future neuropathological and biochemical studies dealing with altered neuronal mechanisms of the disease. The selective loss of SNAP-25 in FTLD may be closely related to the core clinical non-cognitive features of the disease.

Impact of zooplankton grazing on the excystation, viability, and infectivity of the protozoan pathogens Cryptosporidium parvum and Giardia lamblia.

Very little is known about the ability of the zooplankton grazer Daphnia pulicaria to reduce populations of Giardia lamblia cysts and Cryptosporidium parvum oocysts in surface waters. The potential for D. pulicaria to act as a biological filter of C. parvum and G. lamblia was tested under three grazing pressures (one, two, or four D. pulicaria grazers per 66 ml). (Oo)cysts (1 x 10(4) per 66 ml) were added to each grazing bottle along with the algal food Selenastrum capricornutum (6.6 x 10(4) cells per 66 ml) to stimulate normal grazing. Bottles were rotated (2 rpm) to prevent settling of (oo)cysts and algae for 24 h (a light:dark cycle of 16 h:8 h) at 20 degrees C. The impact of D. pulicaria grazing on (oo)cysts was assessed by (i) (oo)cyst clearance rates, (ii) (oo)cyst viability, (iii) (oo)cyst excystation, and (iv) oocyst infectivity in cell culture. Two D. pulicaria grazers significantly decreased the total number of C. parvum oocysts by 52% and G. lamblia cysts by 44%. Furthermore, two D. pulicaria grazers significantly decreased C. parvum excystation and infectivity by 5% and 87%, respectively. Two D. pulicaria grazers significantly decreased the viability of G. lamblia cysts by 52%, but analysis of G. lamblia excystation was confounded by observed mechanical disruption of the cysts after grazing. No mechanical disruption of the C. parvum oocysts was observed, presumably due to their smaller size. The data provide strong evidence that zooplankton grazers have the potential to substantially decrease the population of infectious C. parvum and G. lamblia in freshwater ecosystems.