Charles P. Fontaine

Cytosolic zinc buffering and muffling: Their role in intracellular zinc homeostasis

Our knowledge of the molecular mechanisms of intracellular homeostatic control of zinc ions is now firmly grounded on experimental findings gleaned from the study of zinc proteomes and metallomes, zinc transporters, and insights from the use of computational approaches. A cells repertoire of zinc homeostatic molecules includes cytosolic zinc-binding proteins, transporters localized to cytoplasmic and organellar membranes, and sensors of cytoplasmic free zinc ions. Under steady state conditions, a primary function of cytosolic zinc-binding proteins is to buffer the relatively large zinc content found in most cells to a cytosolic zinc(ii) ion concentration in the picomolar range. Under non-steady state conditions, zinc-binding proteins and transporters act in concert to modulate transient changes in cytosolic zinc ion concentration in a process that is called zinc muffling. For example, if a cell is challenged by an influx of zinc ions, muffling reactions will dampen the resulting rise in cytosolic zinc ion concentration and eventually restore the cytosolic zinc ion concentration to its original value by shuttling zinc ions into subcellular stores or by removing zinc ions from the cell. In addition, muffling reactions provide a potential means to control changes in cytosolic zinc ion concentrations for purposes of cell signalling in what would otherwise be considered a buffered environment not conducive for signalling. Such intracellular zinc ion signals are known to derive from redox modifications of zinc-thiolate coordination environments, release from subcellular zinc stores, and zinc ion influx via channels. Recently, it has been discovered that metallothionein binds its seven zinc ions with different affinities. This property makes metallothionein particularly well positioned to participate in zinc buffering and muffling reactions. In addition, it is well established that metallothionein is a source of zinc ions under conditions of redox signalling. We suggest that the biological functions of transient changes in cytosolic zinc ion concentrations (presumptive zinc signals) complement those of calcium ions in both spatial and temporal dimensions.

Zinquin identifies subcellular compartmentalization of zinc in cortical neurons. Relation to the trafficking of zinc and the mitochondrial compartment

Zinquin (Zn(2+) selective fluorophore), when used to visualize intracellular Zn(2+), typically shows brightly fluorescent perinuclear endosome-like structures, presumably identifying Zn(2+) containing organelles. In this study, zinquin identified numerous and widespread sites of Zn(2+) compartmentalization in primary cultures of embryonic rat cortical neurons. Nuclear fluorescence, however, was absent. We labeled neuronal mitochondria with MitoTracker Green in the presence of zinquin and show that the fluorescent patterns of MitoTracker Green and zinquin were distinct and clearly different in both the perinuclear region and in processes. The mitochondrial compartment was much larger than the sum of the areas of zinquin fluorescence, as indicated by the small amount (<10% MitoTracker Green over zinquin) of overlap of MitoTracker Green on zinquin. Zinquin fluorescence was unaffected by carbonyl cyanide 4-(trifluoromethoxy)phenylhydrazone (FCCP) treatment. The zinquin fluorescent objects were generally spherical in shape with a average diameter of about 0.6 mum. Most fluorescent objects, nearly two thirds on average, appeared to be docked, but both anterograde and retrograde movements were observed by time lapse image analysis. Although some fluorescent objects moved as much as 1 mum in 5 min, typical movements were smaller, usually 0.5 mum or less. Colchicine treatment caused striking aggregation of MitoTracker Green most noticeable in the perinuclear region. Zinquin fluorescence similarly showed reduced distribution throughout the cytoplasm, suggesting that zinquin fluorescent structures were associated with microtubules. Treatment with cytochalasin D had little noticeable effect on either the pattern of zinquin and MitoTracker Green fluorescence or their coincidence. Thus, numerous Zn(2+) sequestering organelles/structures are present in perinuclear regions and processes of cultured neurons and are sometimes found coincident with mitochondria. We demonstrated real time trafficking of sequestered Zn(2+), using zinquin fluorescence, apparently associated with an endosome-like compartment or protein complexes in the cytosol.

Silencing of ZnT1 reduces Zn2+ efflux in cultured cortical neurons.

Zinc dyshomeostasis in brain might be involved in the pathogenesis of a series of brain diseases such as Alzheimers disease and stroke. It is essential that the level of intracellular free Zn2+ in neurons is tightly controlled to maintain a narrow window of optimal concentration. The plasma membrane bound transporter ZnT1 is suggested to lower intracellular Zn2+ concentration. In this study, the function of ZnT1 in cultured cortical neurons was studied. Using vector-based shRNA interference, the expression of this protein was reduced approximately 40% in cultured rat cortical neurons when measured by immunofluorescence using a ZnT1 antibody. Changes in intracellular Zn2+ levels were tracked in individual neurons by microfluorometry using the Zn2+ selective fluorophore, FluoZin3. Unopposed Zn2+ efflux was measured by first loading cultured cortical neurons with Zn2+ then reducing extracellular Zn2+ to near zero by addition of EDTA. Reducing ZnT1 expression caused Zn2+ efflux to decrease compared with the Zn2+ efflux measured in nonsense transfected neurons, suggesting that ZnT1 plays a direct role in Zn2+ efflux. ZnT1 dependent Zn2+ efflux rate was higher in the first 10 min than at later time periods suggesting that ZnT1-mediated efflux was heavily dependent on the intracellular free Zn2+ concentration and/or required an outwardly directed Zn2+ gradient.

Mechanisms of Zn2+ efflux in cultured cortical neurons

Zinc dyshomeostasis in brain might be involved in the pathogenesis of brain diseases such as Alzheimer’s disease and stroke. Resting neurons tightly regulate and maintain low to subnanomolar levels of intracellular free Zn2+, but mechanisms of normal Zn2+ homeostasis are poorly understood. In this study, the mechanisms of transporter‐mediated Zn2+ extrusion across the plasma membrane of cultured cortical neurons were studied. Changes in intracellular free Zn2+ levels were tracked in individual neurons by microfluorometry using a Zn2+ selective fluorophore, FluoZin3. Unopposed Zn2+ efflux was measured by first loading cultured cortical neurons with Zn2+ then reducing extracellular Zn2+ to near zero by addition of EDTA. Studies revealed that the primary means of Zn2+ efflux in cortical neurons required both extracellular Na+ and Ca2+. The actions of either Na+ or Ca2+ on Zn2+ efflux were blunted in the absence of the other cation. Reversed Na+ gradients could induce Zn2+ uptake. The Na+ dependence of Zn2+ efflux was not affected by a small pHo shift (7.6–8); whereas an effect of Ca2+ was not observed at pHo 8. In summary, a Na+, Ca2+/Zn2+ exchanger mechanism is proposed to be the primary transport mechanism that extrudes Zn2+ when neuronal intracellular free Zn2+ levels rise.

Novel Testing of a Biological Safety Cabinet using PCR

The biological safety cabinet is commonly employed to protect both user and product in an increasing number of biotechnology applications. It is recommended that cabinets be fully certified annually, but given the requirements of good laboratory manufacturing practices, more frequent, less disruptive user checks of equipment may be desirable. Furthermore, annual field certifications only determine that cabinets meet basic design and performance parameters and cannot reveal all issues unique to a particular cabinet. This study describes the development of a novel in-laboratory test method using common biotechnology tools that is capable of assessing bioaerosols containment as well as cabinet-specific lateral motion of bioaerosols potentially responsible for product cross-contamination. Genetically engineered viable bacteria releases, followed by colony recovery and gene amplification by polymerase chain reaction, constitute the essence of the new approach. Specifically, a nebulizer was used to release a bioaerosol within a cabinet. Single-stage bioaerosol samplers were simultaneously used to sample the challenge bioaerosol containing bacteria engineered with a plasmid conferring Kanamycin resistance. Recovered challenge bacteria were grown on media containing the antibiotic, and the presence of a DNA fragment in the bacterial plasmid was confirmed. Results demonstrated that there was detectable lateral motion of bioaerosols within the biological safety cabinet tested. The importance of such lateral motion to product cross-contamination is discussed, as are the applications for this novel testing method. It is concluded that the new technique represents an enhanced level of safety cabinet field testing ability available to the end user.