Regenerative therapy in experimental parkinsonism: mixed population of differentiated mouse embryonic stem cells, rather than magnetically sorted and enriched dopaminergic cells provide neuroprotection.

AIM: The objective of the study was to develop regenerative therapy by transplanting varied populations of dopaminergic neurons, differentiated from mouse embryonic stem cells (mES) in the striatum for correcting experimental parkinsonism in rats. METHODS: mES differentiated by default for 7 days in serum-free media (7D), or by enhanced differentiation of 7D in retinoic acid (7R), or dopaminergic neurons enriched by manual magnetic sorting from 7D (SSEA-) were characterized and transplanted in the ipsilateral striatum of 6-hydroxydopamine-induced hemiparkinsonian rats. Neurochemical, neuronal, glial and neurobehavioral recoveries were examined. RESULTS: 7R and SSEA- contained significantly reduced NANOG and high MAP2 mRNA and protein levels as revealed, respectively, by reverse transcriptase-PCR and immunocytochemistry, compared with 7D. Striatal engraftment of 7D resulted in a significantly better behavioral and neurochemical recovery, as compared to the animals that received either 7R or SSEA-. The 7R transplanted animals showed improvement neither in behavior nor in striatal dopamine level. The grafted striatum revealed increased GFAP staining intensity in 7D and SSEA-, but not in 7R cells transplanted group, suggesting a vital role played by glial cells in the recovery. Substantia nigra ipsilateral to the side of the striatum, which received transplants showed more tyrosine hydroxylase immunostained neurons, as compared to 6-hydroxydopamine-infused animals. CONCLUSION: These results demonstrate that default differentiated mixed population of cells are better than sorted, enriched dopaminergic cells, or cells containing more mature neurons for transplantation recovery in hemiparkinsonian rats.

A filtration method for rapid preparation of conjugates for immunoassay.

Modification of protein and other biopolymers by labeling them with small or macromolecules has become a very powerful research tool in biochemistry, molecular biology, diagnostics, and therapeutics. However, current methodologies available for their preparations are not straightforward and take several hours of incubation time. In this paper, we describe a new filtration-assisted technique for covalent conjugation between the reactive functional groups of two different molecules (small or macromolecules). Compared to the current method, this new approach significantly reduces the total reaction time from several hours to just a few minutes. The technique has been used for the preparation of conjugates of a small molecule to a protein such as biotin-BSA conjugate or small molecules to a small molecule such as biotin-tyramine conjugate or protein-protein conjugation such as antibody-horseradish peroxidase conjugate. The procedure consists of filtering the reaction mixture multiple times through membrane micropores with the help of two syringes, which make the cross filtration process less laborious. The method saves time, allows conjugation of less than 1mg protein and produces conjugates better than those obtained by the current methods. Although the present technique has been applied on some common conjugation methods, it provides a potentially general method, and may further be expanded for the synthesis of several other macromolecular conjugates.