Marie-Luise Kiene scite author profile

We were able by using an in vivo pulse‐label technique to trace part of the life cycle of a secretory organelle, the acetylcholine‐storing synaptic vesicle from electromotoneurones of Torpedo marmorata. This technique uses [35S]sulphate incorporation into the cell bodies of the electromotoneurones which results in radioactive labelling of a synaptic vesicle heparansulphate proteoglycan–a major core component. Vesicles are anterogradely transported in the axons at a fast rate as ‘empty’ organelles (VP0 population). In the nerve terminal, maturation of the granule to a population (VP1) fully charged with acetylcholine and ATP occurs. Finally after a longer time interval a change to a third population (VP2) is observed. This population is reduced in diameter as compared to VP0 and VP1 suggesting, in agreement with earlier reports, that it has undergone exo‐endocytosis. The changes from VP0 to VP1 and VP2 are accompanied by a degradation of the core proteoglycan as measured by gel filtration of the 35S‐labelled compound. The results show that vesicles are axonally transported as preformed organelles, exist in the neurone at least in three different populations and that the nerve terminal is the major site of transmitter uptake.

show abstract

Efficient immunoaffinity chromatography of lymphocytes directly from whole blood

Mohr

Przibilla

Leonhardt

et al. 2018

Sci Rep

View full text Add to dashboard Cite

We show that defined lymphocytes can be rapidly purified by immunoaffinity chromatography starting directly from whole blood. The method relies on low-affinity Fab-fragments attached to a column-matrix combined with the reversible Strep-tag technology. Compared to established cell enrichment protocols, the Strep-tag affinity chromatography of cells is independent of erythrocyte lysis or centrifugation steps, allowing for simple cell-enrichment with good yields, high purities, and excellent functionality of purified cells.

show abstract

Synaptic vesicles in electromotoneurones. II. Heterogeneity of populations is expressed in uptake properties; exocytosis and insertion of a core proteoglycan into the extracellular matrix.

Stadler

Kiene

1987

The EMBO Journal

View full text Add to dashboard Cite

The three populations of synaptic vesicles in electromotor nerve terminals were analysed quantitatively. Empty vesicles (VP0), fully charged vesicles (VP1) and charged but smaller VP2‐type vesicles are present in approximately equal amounts in the nerve terminal. The populations show differences in the kinetics of in vitro uptake of acetylcholine, ATP and Ca2+. VP0 and VP2 accumulate acetylcholine and ATP but no Ca2+, whereas VP1 shows negligible acetylcholine and ATP but high Ca2+ uptake. Thus the expression of uptake properties of this secretory organelle depend on the stage it has reached in its life cycle and might constitute a signal for processing. VP2 was found to contain much less core proteoglycan than VP0 and VP1 indicating that part of it has been lost by exocytosis. In synaptic extracellular matrix containing fractions an antigen is detectable that cross‐reacts with an antiserum against the vesicle proteoglycan. This material elutes upon gel filtration in a position similar to a smaller form of proteoglycan found in vesicles. We conclude that the electromotor nerve terminal releases a proteoglycan by the regulated secretory pathway that is deposited in the extracellular matrix. It might have a function in keeping pre‐ and postsynaptic structures in alignment constituting a transsynaptic signal. Based on the findings described, a model of the vesicles' life‐cycle is discussed, whereby the VP2 population is the major source of quantal release of acetylcholine.

show abstract

Nervous system myelin in the electric ray, Torpedo marmorata: Morphological characterization of the membrane and biochemical analysis of its protein components

Waehneldt

Kiene

Malotka

et al. 1984

Neurochemistry International

View full text Add to dashboard Cite

Lymphocyte enrichment using CD81‐targeted immunoaffinity matrix

et al. 2016

View full text Add to dashboard Cite

In mass cytometry, the isolation of pure lymphocytes is very important to obtain reproducible results and to shorten the time spent on data acquisition. To prepare highly purified cell suspensions of peripheral blood lymphocytes for further analysis on mass cytometer, we used the new CD811 immune affinity chromatography cell isolation approach. Using 21 metal conjugated antibodies in a single tube we were able to identify all basic cell subsets and compare their relative abundance in final products obtained by density gradient (Ficoll-Paque) and immune affinity chromatography (CD811 T-catch TM ) isolation approach. We show that T-catch isolation approach results in purer final product than Ficoll-Paque (P values 0.0156), with fewer platelets bound to target cells. As a result acquisition time of 10 5 nucleated cells was 3.5 shorter. We then applied unsupervised high dimensional analysis viSNE algorithm to compare the two isolation protocols, which allowed us to evaluate the contribution of unsupervised analysis over supervised manual gating. ViSNE algorithm effectively characterized almost all supervised cell subsets. Moreover, viSNE uncovered previously overseen cell subsets and showed inaccuracies in Maxpar TM Human peripheral blood phenotyping panel kit recommended gating strategy. These findings emphasize the use of unsupervised analysis tools in parallel with conventional gating strategy to mine the complete information from a set of samples. They also stress the importance of the impurity removal to sensitively detect rare cell populations in unsupervised analysis. V C 2016International Society for Advancement of Cytometry

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.