Cohen syndrome-associated protein COH1 physically and functionally interacts with the small GTPase RAB6 at the Golgi complex and directs neurite outgrowth.

Postnatal microcephaly, intellectual disability, and progressive retinal dystrophy are major features of autosomal recessive Cohen syndrome, which is caused by mutations in the gene COH1 (VPS13B). We have recently identified COH1 as a Golgi-enriched scaffold protein that contributes to the structural maintenance and function of the Golgi complex. Here, we show that association of COH1 with the Golgi complex depends on the small GTPase RAB6. RNAi-mediated knockdown of RAB6A/A' prevents the localization of COH1 to the Golgi complex. Expression of the constitutively inactive RAB6_T27N mutant led to an increased solubilization of COH1 from lipid membrane preparations. Co-IP experiments confirmed the physical interaction of COH1 with RAB6 that preferentially occurred with the constitutively active RAB6_Q72L mutants. Depletion of COH1 in primary neurons negatively interfered with neurite outgrowth, indicating a causal link between the integrity of the Golgi complex and axonal outgrowth. We conclude that COH1 is a RAB6 effector protein and that reduced brain size in Cohen syndrome patients likely results from impaired COH1 function at the Golgi complex, causing decreased neuritogenesis.

Comparative analysis of detection limits and specificity of molecular diagnostic markers for three pathogens (Microsporidia, Nosema spp.) in the key pollinators Apis mellifera and Bombus terrestris.

Global pollinator decline has recently been discussed in the context of honey and bumble bee infections from various pathogens including viruses, bacteria, microsporidia and mites. The microsporidian pathogens Nosema apis, Nosema ceranae and Nosema bombi may in fact be major candidates contributing to this decline. Different molecular and non-molecular detection methods have been developed; however, a comparison, especially of the highly sensitive PCR based methods, is currently lacking. Here, we present the first comparative quantitative real-time PCR study of nine Nosema spp. primers within the framework of primer specificity and sensitivity. With the help of dilution series of defined numbers of spores, we reveal six primer pairs amplifying N. apis, six for N. bombi and four for N. ceranae. All appropriate primer pairs detected an amount of at least 10(4) spores, the majority of which were even as sensitive to detect such low amounts as 10(3) to ten spores. Species specificity of primers was observed for N. apis and N. bombi, but not for N. ceranae. Additionally, we did not find any significant correlation for the amplified fragments with PCR efficiency or the limit of detection. We discuss our findings on the background of false positive and negative results using quantitative real-time PCR. On the basis of these results, future research might be based on appropriate primer selection depending on the experimental needs. Primers may be selected on the basis of specificity or sensitivity. Pathogen species and load may be determined with higher precision enhancing all kinds of diagnostic studies.

Effects of thermoresponsivity and softness on skin penetration and cellular uptake of polyglycerol-based nanogels.

Nanogels are water soluble cross-linked polymer networks with nanometer size dimensions that can be designed to incorporate different types of compounds and are promising carrier systems for drugs and biological molecules. In this study, the interactions of thermoresponsive nanogels (tNGs) with the human skin barrier and underlying epidermis cells were investigated with the aim of using such macromolecules to improve dermal and transdermal drug delivery. The investigated tNGs were made of acrylated dendritic polyglycerol, as water soluble cross-linker, and of oligo ethylene glycol methacrylate (OEGMA) as subunit conferring thermoresponsive properties. tNGs with different polymer transition temperatures were tagged with Rhodamine B (RhdB) and analyzed for their physicochemical properties. We found that tNGs with cloud point temperatures (Tcps) of 38 °C (tNG-RhdB-T38) lost softness (measured by PeakForce quantitative nanomechanics, QNM) and aggregated to bigger sized particles (measured as increase of particle average size by dynamic light scattering, DLS) when temperature changed from 15 to 37 °C. On the contrary, at the same conditions, tNGs with higher Tcps (tNG-RhdB-T55) did not show any significant changes of these characteristics. Applied on excised human skin, both tNGs penetrated deep in the stratum corneum (SC). Small amounts of tNGs were detected also in cells of the viable epidermis. Interestingly, whereas tNG softness correlated with higher penetration in SC, a better cellular uptake was observed for the thermoresponsive tNG-RhdB-T38. We conclude that soft nanocarriers possess a high SC penetration ability and that thermoresponsive nanogels are attractive carrier systems for the targeting of drugs to epidermis cells.