Enzo Wanke

Isolation and cloning of multipotential stem cells from the embryonic human CNS and establishment of transplantable human neural stem cell lines by epigenetic stimulation

Stem cells that can give rise to neurons, astroglia, and oligodendroglia have been found in the developing and adult central nervous system (CNS) of rodents. Yet, their existence within the human brain has not been documented, and the isolation and characterization of multipotent embryonic human neural stem cells have proven difficult to accomplish. We show that the developing human CNS embodies multipotent precursors that differ from their murine counterpart in that they require simultaneous, synergistic stimulation by both epidermal and fibroblast growth factor-2 to exhibit critical stem cell characteristics. Clonal analysis demonstrates that human C NS stem cells are multipotent and differentiate spontaneously into neurons, astrocytes, and oligodendrocytes when growth factors are removed. Subcloning and population analysis show their extensive self-renewal capacity and functional stability, their ability to maintain a steady growth profile, their multipotency, and a constant potential for neuronal differentiation for more than 2 years. The neurons generated by human stem cells over this period of time are electrophysiologically active. These cells are also cryopreservable. Finally, we demonstrate that the neuronal and glial progeny of long-term cultured human CNS stem cells can effectively survive transplantation into the lesioned striatum of adult rats. Tumor formation is not observed, even in immunodeficient hosts. Hence, as a consequence of their inherent biology, human CNS stem cells can establish stable, transplantable cell lines by epigenetic stimulation. These lines represent a renewable source of neurons and glia and may significantly facilitate research on human neurogenesis and the development of clinical neural transplantation.

A novel inward‐rectifying K+ current with a cell‐cycle dependence governs the resting potential of mammalian neuroblastoma cells.

1. Human and murine neuroblastoma cell lines were used to investigate, by the whole‐cell patch‐clamp technique, the properties of a novel inward‐rectifying K+ current (IIR) in the adjustment of cell resting potential (Vrest), which was in the range ‐40 to ‐20 mV. 2. When elicited from a holding potential of 0 mV, IIR was completely inactivated with time constants ranging from 13 ms at ‐140 mV to 4.5 s at ‐50 mV. The steady‐state inactivation curve (h(V)) was found to be independent of [Na+]o and [K+]o (2‐80 mM) and could be fitted to a Boltzmann curve with a steep slope factor of 5‐6, and a V1/2 around Vrest. Divalent ion‐free extracellular solutions shifted h(V) to the left by about 28 mV. 3. Peak chord conductance, whose maximal value was approximately proportional to the square root of [K+]o, could be fitted to a Boltzmann curve independently of [K+]o, with a V1/2 value around ‐48 mV and a slope factor of 18. Extracellular Cs+ and Ba2+ blocked the IIR in a concentration‐ and voltage‐dependent manner, but Ba2+ was less effective than it is on classical inward‐rectifier channels. 4. Under control culture conditions the values of Vrest and V1/2 of h(V) varied widely among cells. The knowledge of V1/2 proved crucial or the theoretical prediction of Vrest. After cell synchronization in the G0‐G1 phase of the cell cycle, or at the G1‐S boundaries, the cells reduced their variability of h(V). The same occurred after cell synchronization in G1 by treatment with retinoic acid. 5. The experimental data could be fitted to a classical model of an inward rectifier, after removing the dependence of conductance activation on (V‐EK), and incorporating an inactivation with an intrinsic voltage dependence. Moreover, the model predicts, for this novel inward rectifier and in contrast with the classical inward rectifier, the incapacity of maintaining, in physiological media, a Vrest more negative than ‐35 to ‐40 mV, which is an important feature of cancer cells.

herg1 Gene and HERG1 Protein Are Overexpressed in Colorectal Cancers and Regulate Cell Invasion of Tumor Cells

The acquisition of the capacity to invade surrounding tissues confers a more malignant phenotype to tumor cells and is necessary for the establishment of metastases. The understanding of the molecular mechanisms underlying cell invasion in human solid tumors such as colorectal cancers could provide not only more sensitive prognostic analyses but also novel molecular targets for cancer therapy. We report in this article that K+ ion channels belonging to the HERG family are important determinants for the acquisition of an invasive phenotype in colorectal cancers. The herg1 gene and HERG1 protein are expressed in many colon cancer cell lines, and the activity of HERG channels modulates colon cancer cell invasiveness. Moreover, the amount of HERG1 protein expressed on the plasma membrane is directly related to the invasive phenotype of colon cancer cells. Finally, both the herg1 gene and HERG1 protein were expressed in a high percentage of primary human colorectal cancers, with the highest incidence occurring in metastatic cancers, whereas no expression could be detected either in normal colonic mucosa or in adenomas.

Cell Cycle-dependent Expression of HERG1 and HERG1B Isoforms in Tumor Cells

The role of K+ channel activity during cell cycle progression has become a research topic of considerable interest. Blocking of K+ channels inhibits the proliferation of many cell types, although the mechanism of this inhibition is unclear. There is speculation that K+channels differentially regulate the electrical potential of the plasma membrane (V m ) during proliferation. We have demonstrated that in tumor cells the value of V m is clamped to rather depolarized values by K+ channels belonging to the HERG family. We report here that tumor cell lines preferentially express the herg1 gene and a truncated,N-deleted form that corresponds to herg1b. This alternative transcript is also expressed in human primary acute myeloid leukemias. Both HERG1 and HERG1B proteins are expressed on the plasma membrane of tumor cells and can form heterotetramers. The expression of HERG protein isoforms is strongly cell cycle-dependent, accounting for variations in HERG currents along the mitotic cycle. Moreover, the blocking of HERG channels dramatically impairs cell growth of HERG-bearing tumor cells. These results suggest that modulated expression of different K+ channels is the molecular basis of a novel mechanism regulating neoplastic cell proliferation.

HERG potassium channels are constitutively expressed in primary human acute myeloid leukemias and regulate cell proliferation of normal and leukemic hemopoietic progenitors.

An important target in the understanding of the pathogenesis of acute myeloid leukemias (AML) relies on deciphering the molecular features of normal and leukemic hemopoietic progenitors. In particular, the analysis of the mechanisms involved in the regulation of cell proliferation is decisive for the establishment of new targeted therapies. To gain further insight into this topic we report herein a novel approach by analyzing the role of HERG K+ channels in the regulation of hemopoietic cell proliferation. These channels, encoded by the human ether-a-gò-gò-related gene (herg), belong to a family of K+ channels, whose role in oncogenesis has been recently demonstrated. We report here that herg is switched off in normal peripheral blood mononuclear cells (PBMNC) as well as in circulating CD34+ cells, however, it is rapidly turned on in the latter upon induction of the mitotic cycle. Moreover, hergappears to be constitutively activated in leukemic cell lines as well as in the majority of circulating blasts from primary AML. Evidence is also provided that HERG channel activity regulates cell proliferation in stimulated CD34+ as well as in blast cells from AML patients. These results open new perspectives on the pathogenetic role of HERG K+ channels in leukemias.

A novel role for HERG K+ channels: spike-frequency adaptation.

1 The regular firing of a Hodgkin‐Huxley neurone endowed with fast Na+ and delayed K+ channels can be converted into adapting firing by appending HERG (human eag‐related gene) channels. 2 The computer model predictions were verified by studying the firing properties of F‐11 DRG neurone x neuroblastoma hybrid cells induced to differentiate by long‐term exposure to retinoic acid. These cells, which express HERG currents (IHERG), show clear spike‐frequency adaptation of their firing when current clamped with long depolarizations. 3 In agreement with the prediction, the selective blocking of IHERG by class III antiarrhythmic drugs always led to the disappearance of the spike‐frequency adaptation, and the conversion of adapting firing to regular firing. 4 It is proposed that, in addition to their role in the repolarization of the heart action potential, HERG channels may sustain a process of spike‐frequency adaptation, and hence contribute to the control of burst duration in a way that is similar to that of the K+ currents, IAHP, IC and IM. In addition to the known cardiac arrhythmia syndrome (LQT2), genetic mutations or an altered HERG expression could lead to continuous hyperexcitable states sustained by the inability of nerve or endocrine cells to accommodate to repetitive stimuli. This might help in clarifying the pathogenesis of still undefined idiopathic familial epilepsies.

HERG potassium channels are more frequently expressed in human endometrial cancer as compared to non-cancerous endometrium

HERG K+channels, besides contributing to regulate cardiac and neuronal excitability, are preferentially expressed in tumour cell lines of different histogenesis, where their role in the development and maintenance of the neoplastic phenotype is under study. We show here that both herg gene and HERG protein are expressed with high frequency in primary human endometrial cancers, as compared to normal and hyperplastic endometrium. RT-PCR and immunohistochemistry, using specific anti-HERG antibodies developed in our laboratory, were applied to tissue specimens obtained from 18 endometrial cancers and 11 non-cancerous endometrial tissues. herg RNA and HERG protein are expressed in 67% and 82%, respectively, of cancerous, while in only 18% of non-cancerous tissues. In particular, no expression was found in endometrial hyperplasia. Moreover, electrophysiological experiments confirmed the presence of functioning HERG channels on the plasma membrane of tumour cells. On the whole, these data are the first demonstration of the presence of HERG channels in primary human neoplasias, and could candidate HERG as a potential tool capable of marking cancerous versus hyperplastic endometrial growth.

Action potentials recorded with patch-clamp amplifiers: are they genuine?

A growing number of experimental studies have used patch-clamp amplifiers (PCAs) in the current-clamp (CC) mode to investigate classical excitability. In this paper we show that the measurements obtained in this way are affected by errors due to the electronic design of the PCA input section. We present experimental evidence of such errors, and demonstrate that they derive from PCA current absorption. Moreover, we propose a new PCA input-circuit configuration for the CC mode, which is suitable for accurately recording physiological voltage signals and is perfectly compatible with the standard voltage-clamp mode.

Glucose- and arginine-induced insulin secretion by human pancreatic {beta}-cells: the role of HERG K+ channels in firing and release

The human ether‐a‐go‐go‐related genes (herg) are expressed in tissues other than heart and brain where the HERG K+ channels are known to regulate the repolarization of the heart action potential and the neuronal spike‐frequency accommodation. We provide evidence that herg1 transcripts are present in human pancreatic islets that were used to study both insulin secretion and electrical activity with radioimmunoassay and single cell perforated patch‐clamp techniques, respectively. Glucose‐ and arginine‐induced islets insulin secretion data suggested a net increase of release under perfusion with antiarrhythmic drugs known to selectively block HERG channels. Indeed we could routinely isolate a K+ current that was recognized as biophysically and pharmacologically similar to the HERG current. An analysis of the glucose‐ and arginine‐induced electrical activity (several applications during 30 min) in terms of firing frequency and putative insulin release was done in control and in the presence of selective blockers of HERG channels: the firing frequency and the release increased by 32% and 77%, respectively. It is concluded that HERG channels have a crucial role in regulating insulin secretion and firing of human β‐cells. This raises the possibility that some genetically characterized hyperinsulinemic diseases of unknown origin might involve mutations in the HERG channels.—Rosati, B., Marchetti, P., Crociani, O., Lecchi, M., Lupi, R., Arcangeli, A., Olivotto, M., Wanke, E. Glucose‐ and arginine‐in‐duced insulin secretion by human pancreatic β‐cells: the role of HERG K+ channels in firing and release. The FASEB J. 14, 2601–2610 (2000)

Ionic mechanisms underlying burst firing in pyramidal neurons: intracellular study in rat sensorimotor cortex

In in vitro slices prepared from rat sensorimotor cortex, intracellular recordings were obtained from 107 layer V pyramidal neurons, subsequently injected with biocytin for morphological reconstruction. Of the 107 neurons, 59 (55.1%) were identified as adapting (45) or non-adapting (13) regular spiking neurons (RS), and 48 (44.9%) as intrinsically bursting (IB) neurons discharging with an initial cluster of action potentials, which tended to recur rhythmically in a subset of 19 cells. The block of IAR by extracellular Cs+ did not affect burst generation, but enhanced the tendency to reburst in IB neurons. A similar effect was induced by other procedures affecting K(+)-dependent post-burst hyperpolarization. In IB neurons Ca2+ spikes had a longer decay time than in RS neurons, however selective blockers of both low and high threshold Ca2+ conductances failed to impair bursting activity. On the contrary, the perfusion of the slices with 0.5-1 microM TTX suppressed bursting behaviour in a critical time interval preceding the complete block of Na(+)-dependent action potentials. It is concluded that the persistent Na+ current INAP is the most important intrinsic factor for the typical firing properties of IB neurons, while Ca2+ and K+ conductances appear to contribute towards shaping bursts and controlling their recurrence rate. The morphology, connectivity and physiological properties of adapting and non-adapting RS neurons are particularly suited to the processing of respectively phasic and tonic inputs, whereas the properties of IB neurons are consistent with their suggested role in cortical rhythmogenesis and in the pathophysiological synchronized activities underlying epileptogenesis.