Jürgen Bereiter-Hahn

Dimethylaminostyrylmethylpyridiniumiodine (DASPMI) as a fluorescent probe for mitochondria in situ

An investigation has been made on the properties of dimethylaminostyrylmethylpyridiniumiodine (DASPMI), its reaction with isolated pigeon heart mitochondria and its suitability as a vital strain for mitochondria in situ. DASPMI is a low toxicity specific vital stain for mitochondria in living cells. In vitro dye concentrations over 6 nmol/mg protein inhibit fast (state 3) respiration after a preincubation time of more than 5 min in the presence of substrate. No uncoupling was observed. Energization of pigeon heart mitochondria by addition of ATP or various substrated yields an average 8.5-fold increase in fluorescence intensity in relation to DASPMI-stained mitochondria that are under anoxia, substrate deficiency, or under the influence of respiratory inhibitors, or uncouplers. The alterations in fluorescence intensity are not primarily due to ion movements or pH changes. The amount of dye (2.96+/-0.8 nmol) yielding maximal fluorescence response with 1 mg mitochondrial protein remains constant during energization of mitochondria. As indicated by electron microscopic studies the observed changes in emission intensity may be related to changes in the fine structural organisation of cristae. A remarkable difference exists between isolated mitochondria and mitochondria in situ with respect to the reaction to cyanide. According to the reported results DASPMI will be a useful probe for the investigation of mitochondrial activities in living cells.

The polo‐like protein kinases Fnk and Snk associate with a Ca2+‐ and integrin‐binding protein and are regulated dynamically with synaptic plasticity

In order to stabilize changes in synaptic strength, neurons activate a program of gene expression that results in alterations of their molecular composition and structure. Here we demonstrate that Fnk and Snk, two members of the polo family of cell cycle associated kinases, are co‐opted by the brain to serve in this program. Stimuli that produce synaptic plasticity, including those that evoke long‐term potentiation (LTP), dramatically increase levels of both kinase mRNAs. Induced Fnk and Snk proteins are targeted to the dendrites of activated neurons, suggesting that they mediate phosphorylation of proteins in this compartment. Moreover, a conserved C‐terminal domain in these kinases is shown to interact specifically with Cib, a Ca2+‐ and integrin‐binding protein. Together, these studies suggest a novel signal transduction mechanism in the stabilization of long‐term synaptic plasticity.

Short- and long-term alterations of mitochondrial morphology, dynamics and mtDNA after transient oxidative stress

Cells are exposed during their life span to fluctuating levels of reactive oxygen species (ROS). To investigate the effects of a single ROS boost in vitro, human endothelial cells (HUVEC) were treated with one short-term dose of hydrogen peroxide. This treatment resulted in a short, dose-dependent ROS peak that caused transient changes in the mitochondrial morphology and fine structure, in the frequency of mitochondrial fission and fusion and in the mRNA levels of distinct fission and fusion factors. Treatment with a higher dose induced prolonged mtDNA damage; these cells exhibited a significantly shortened replicative lifespan, indicating dose-dependent effects of oxidative stress on mitochondria.

Decreased expression of Drp1 and Fis1 mediates mitochondrial elongation in senescent cells and enhances resistance to oxidative stress through PINK1

Mitochondria display different morphologies, depending on cell type and physiological situation. In many senescent cell types, an extensive elongation of mitochondria occurs, implying that the increase of mitochondrial length in senescence could have a functional role. To test this hypothesis, human endothelial cells (HUVECs) were aged in vitro. Young HUVECs had tubular mitochondria, whereas senescent cells were characterized by long interconnected mitochondria. The change in mitochondrial morphology was caused by downregulation of the expression of Fis1 and Drp1, two proteins regulating mitochondrial fission. Targeted photodamage of mitochondria induced the formation of reactive oxygen species (ROS), which triggered mitochondrial fragmentation and loss of membrane potential in young cells, whereas senescent cells proved to be resistant. Alterations of the Fis1 and Drp1 expression levels also influenced the expression of the putative serine-threonine kinase PINK1, which is associated with the PARK6 variant of Parkinsons disease. Downregulation of PINK1 or overexpression of a PINK1 mutant (G309D) increased the sensitivity against ROS in young cells. These results indicate that there is a Drp1- and Fis1-induced, and PINK1-mediated protection mechanism in senescent cells, which, when compromised, could contribute to the age-related progression of Parkinsons disease and arteriosclerosis.

Morpho-dynamic changes of mitochondria during ageing of human endothelial cells

Mitochondrial morphology is regulated in many cultured eukaryotic cells by fusion and fission of mitochondria. A tightly controlled balance between fission and fusion events is required to ensure normal mitochondrial and cellular functions. During ageing, mitochondria are undergoing significant changes on the functional and morphological level. The effect of ageing on fusion and fission of mitochondria and consequences of altered fission and fusion activity are still unknown although theoretical models on ageing consider the significance of these processes. Human umbilical vein endothelial cells (HUVECs) have been established as a cell culture model to follow mitochondrial activity and dysfunction during the ageing process. Mitochondria of old and postmitotic HUVECs showed distinct alterations in overall morphology and fine structure, and furthermore, loss of mitochondrial membrane potential. In parallel, a decrease of intact mitochondrial DNA (mtDNA) was observed. Fission and fusion activity of mitochondria were quantified in living cells. Mitochondria of old HUVECs showed a significant and equal decrease of both fusion and fission activity indicating that these processes are sensitive to ageing and could contribute to the accumulation of damaged mitochondria during ageing.

Cooperative phosphorylation including the activity of polo-like kinase 1 regulates the subcellular localization of cyclin B1

The cyclin-dependent kinase 1 (Cdc2)/cyclin B1 complex performs cardinal roles for eukaryotic mitotic progression. Phosphorylation of four serine residues within cyclin B1 promotes the rapid nuclear translocation of Cdc2/cyclin B1 at the G2/M transition. Still, the role of individual phosphorylation sites and their corresponding kinases remain to be elucidated. Polo-like kinase 1 (Plk1) shows a spatial and temporal distribution which makes it a candidate kinase for the phosphorylation of cyclin B1. We could demonstrate the interaction of both proteins in mammalian cells. Plk1 phosphorylated wild-type cyclin B1 expressed in bacteria and in mammalian cells. Ser-133 within the cytoplasmic retention signal (CRS) of cyclin B1, which regulates the nuclear entry of the heterodimeric complex during prophase, is a target of Plk1. In contrast, MAPK (Erk2) and MPF phosphorylate Ser-126 and Ser-128 within the CRS. Phosphorylation of CRS by MAPK (Erk2) prior to Plk1 treatment induced enhanced phosphorylation of cyclin B1 by Plk 1 suggesting a synergistic action of both enzymes towards cyclin B1. In addition, pretreatment of cyclin B1 by MAPK (Erk2) altered the phosphorylation pattern of Plk 1. Mutation of Ser-133 to Ala decreased the phosphorylation of cyclin B1 in vivo. An immunofluorescence study revealed that a mutation of Ser-133 reduced the nuclear import rate of cyclin B1. Still, multiple serine mutations are required to prevent nuclear translocation completely indicating that orchestrated phosphorylation within the CRS triggers rapid import of cyclin B1.

Autophagy proteins LC3B, ATG5 and ATG12 participate in quality control after mitochondrial damage and influence lifespan

Mitochondrial health is maintained by the quality control mechanisms of mitochondrial dynamics (fission and fusion) and mitophagy. Decline of these processes is thought to contribute to aging and neurodegenerative diseases. To investigate the role of mitochondrial quality control in aging on the cellular level, human umbilical vein endothelial cells (HUVEC) were subjected to mitochondria-targeted damage by combining staining of mitochondria and irradiation. This treatment induced a short boost of reactive oxygen species, which resulted in transient fragmentation of mitochondria followed by mitophagy, while mitochondrial dynamics were impaired. Furthermore, targeted mitochondrial damage upregulated autophagy factors LC3B, ATG5 and ATG12. Consequently these proteins were overexpressed in HUVEC as an in vitro aging model, which significantly enhanced the replicative life span up to 150% and the number of population doublings up to 200%, whereas overexpression of LAMP-1 did not alter the life span. Overexpression of LC3B, ATG5 and ATG12 resulted in an improved mitochondrial membrane potential, enhanced ATP production and generated anti-apoptotic effects, while ROS levels remained unchanged and the amount of oxidized proteins increased. Taken together, these data relate LC3B, ATG5 and ATG12 to mitochondrial quality control after oxidative damage, and to cellular longevity.

Functional interaction of the cation channel transient receptor potential vanilloid 4 (TRPV4) and actin in volume regulation.

Many vertebrate cells react to hypotonic conditions with swelling, followed by an active downregulation of the cell volume; a progress called regulatory volume decrease (RVD). While the actual process of volume decrease by loss of osmotically active molecules like K(+) and Cl(-), followed by water efflux has been extensively investigated, the signal for activation of RVD still remains obscure. Studies with different cell lines demonstrated a participation of the cation channel transient receptor potential vanilloid 4 (TRPV4) as well as the actin cytoskeleton in volume regulation. Therefore, we analyzed putative links between TRPV4 and F-actin in RVD in HaCaT keratinocytes and CHO cells. Laser scanning microscopy studies revealed a distinct colocalization of TRPV4 and actin in highly dynamic membrane structures, such as microvilli, filopodia and lamellipodia edges. After treatment of cells with the actin-destabilizing reagent latrunculin A, TRPV4 and F-actin no longer colocalized within the membrane. In accordance with these data, close interaction between TRPV4 and F-actin was revealed by FRAP and FRET studies. For functional analysis, CHO cells that endogenously do not express TRPV4, were transfected with recombinant TRPV4, which rendered them RVD-competent. Treatment with latrunculin A abolished both, RVD and the accompanying rise of [Ca(2+)](i) after hypotonic stress in TRPV4-transfected CHO cells. Taken together, our data demonstrate a functional interaction between TRPV4 and F-actin in sensing hypotonicity and the onset of RVD.

Structural implications of mitochondrial dynamics

Mitochondrial components are continuously distributed throughout the whole chondriome of a cell by fusion and fission. Thus, a single mitochondrion represents a transient fraction of the chondriome. Mitochondrial dynamics are responsible for intracellular distribution and reaction of mitochondria to functional requirements. Dynamics occur on different levels: overall morphology, inner membrane–matrix compartment, turnover and rearrangements of mitochondrial proteins and DNA. Electron micrographs of serial sections of human umbilical vein endothelial cells reveal perinuclear mitochondria of extreme length and with branches in those cells that also have short peripheral mitochondria. Interactions of mitochondria with cytoskeletal elements are revealed in cells treated with cytochalasin D to destroy actin fibrillar structures or after disassembling microtubule by nocodazole. In the latter case mitochondria not only become immobilized, they also acquire a multiple ring structure. In F‐actin‐disturbed cells, motility (shape changes in particular) is increased and the mitochondria become elongated. Mechanisms of how F‐actin might render mitochondria immobile may involve dynamin‐related protein 1 (DRP1) or interaction with anion channels. This may be responsible for the lack of mitochondrial motility in senescent cells. Fusion between mitochondria revealed local fluctuations of mitochondrial red fluorescent protein (mtRFP), indicating novel fast inner membrane reorganizations. Mitochondrial dynamics result from a complex interplay between the molecular organization of the inner membrane–matrix complex and cytoskeletal elements outside.

Cell property determination from the acoustic microscope generated voltage versus frequency curves

Among the methods for the determination of mechanical properties of living cells acoustic microscopy provides some extraordinary advantages. It is relatively fast, of excellent spatial resolution and of minimal invasiveness. Sound velocity is a measure of the stiffness or Youngs modulus of the cell. Attenuation of cytoplasm is a measure of supramolecular interactions. These parameters are of crucial interest for studies of cell motility, volume regulations and to establish the functional role of the various elements of the cytoskeleton. Using a phase and amplitude sensitive modulation of a scanning acoustic microscope (Hillman et al., 1994, J. Alloys Compounds. 211/212:625-627) longitudinal wave speed, attenuation and thickness profile of a biological cell are obtained from the voltage versus frequency or V(f) curves. A series of pictures, for instance in the frequency range 980-1100 MHz with an increment of 20 MHz, allows the experimental generation of V(f) curves for each pixel while keeping the lens-specimen distance unchanged. Both amplitude and phase values of the V(f) curves are used for obtaining the cell properties and the cell thickness profile. The theoretical analysis shows that the thin liquid layer, between the cell and the substrate, has a strong influence on the reflection coefficient and should not be ignored during the analysis. Cell properties, cell profile and the thickness of the thin liquid layer are obtained from the V(f) curves by the simplex inversion algorithm. The main advantages of this new method are that imaging can be done near the focal plane, therefore an optimal signal to noise ratio is achieved, no interference with Rayleigh waves occurs, and the method requires only an approximate estimate of the material properties of the solid substratum where the cells are growing on.