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1. Advances in Charcot–Marie–Tooth Disease Research: Cellular Function of CMT-Related Proteins, Transgenic Animal Models, and Pathomechanisms

Author: Hans W. Müller, Ueli Suter, Christine Van Broeckhoven, O. Haneman, E. Nelis, V. Timmerman, S. Sancho, L. Barrio, P. Bolhuis, R. Dermietzel, M. Frank, A. Gabreëls-Festen, C. Gillen, N. Haites, G. Levi, E. Mariman, R. Martini, K. Nave, B. Rautenstrauss, M. Schachner, A. Schenone, C. Schneider, M. Schröder, and K. Willecke
Subjects: Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract: The First Workshop of the European Consortium on Charcot–Marie–Tooth (CMT) disease brought together neuroscientists, molecular and cell biologists, neuropathologists, neurologists, and geneticists with a common interest in the understanding of the fundamental mechanisms that underlie the pathogenesis of CMT. The interdisciplinary group of 25 expert scientists discussed recent advances in (i) molecular genetics and histopathology of CMT, (ii) development of suitable animal models, (iii) understanding of the cellular function of CMT-related proteins, and (iv) studies using nerve biopsies from CMT patients. In this minireview, we summarize the key findings presented and discuss their impact on CMT research.
Published: 1997
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2. Advances in Charcot-Marie-Tooth disease research: cellular function of CMT-related proteins, transgenic animal models, and pathomechanisms

Author: A.A.W.M. Gabreëls-Festen, C. Van Broeckhoven, G. Levi, Hans Werner Müller, A. Schenone, M. Frank, K. Willecke, R. Martini, Vincent Timmerman, B. Rautenstrauss, R. Dermietzel, C. Schneider, N. Haites, O. Haneman, Edwin C. M. Mariman, Ueli Suter, C. Gillen, M. Schröder, Eva Nelis, M. Schachner, S. Sancho, Klaus-Armin Nave, L. Barrio, and P.A. Bolhuis
Subjects: congenital, hereditary, and neonatal diseases and abnormalities, medicine.medical_specialty, business.industry, Neuromusculaire en neurometabole aandoeningen, Transgene, Clinical description and delineation of genetic syndromes, Disease, lcsh:RC321-571, nervous system diseases, Tooth disease, Neurology, Neuromuscular and neurometabolic disorders, Molecular genetics, medicine, business, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries), lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Neuroscience, Klinische beschrijving en moleculaire definiëring van genetische syndromen, Function (biology)
Abstract: The First Workshop of the European Consortium on Charcot–Marie–Tooth (CMT) disease brought together neuroscientists, molecular and cell biologists, neuropathologists, neurologists, and geneticists with a common interest in the understanding of the fundamental mechanisms that underlie the pathogenesis of CMT. The interdisciplinary group of 25 expert scientists discussed recent advances in (i) molecular genetics and histopathology of CMT, (ii) development of suitable animal models, (iii) understanding of the cellular function of CMT-related proteins, and (iv) studies using nerve biopsies from CMT patients. In this minireview, we summarize the key findings presented and discuss their impact on CMT research.
Published: 1997

3. Biophysical properties of gap junction channels formed by mouse connexin40 in induced pairs of transfected human HeLa cells

Author: C. Elfgang, Feliksas F. Bukauskas, K. Willecke, and Robert Weingart
Subjects: Time Factors, Biophysics, Analytical chemistry, Transfection, Molecular physics, Connexins, Ion Channels, Membrane Potentials, Mice, Electrical resistivity and conductivity, Animals, Humans, Ion channel, Probability, Membrane potential, Chemistry, Electric Conductivity, Temperature, Pipette, Gap junction, Gap Junctions, State (functional analysis), Recombinant Proteins, Clone Cells, Ion Channel Gating, Temperature coefficient, HeLa Cells, Research Article
Abstract: A clone of human HeLa cells stably transfected with mouse connexin40 DNA was used to examine gap junctions. Two separate cells were brought into physical contact with each other ("induced cell pair") to allow insertion of gap junction channels and, hence, formation of a gap junction. The intercellular current flow was measured with a dual voltage-clamp method. This approach enabled us to study the electrical properties of gap junction channels (cell pairs with a single channel) and gap junctions (cell pairs with many channels). We found that single channels exhibited multiple conductances, a main state (gamma j(main state)), several substates (gamma j(substates)), a residual state (gamma j (residual state)), and a closed state (gamma j(closed state)). The gamma j(main state) was 198 pS, and gamma j(residual state) was 36 pS (temperature, 36–37 degrees C; pipette solution, potassium aspartate). Both properties were insensitive to transjunctional voltage, Vj. The transitions between the closed state and an open state (i.e., residual state, substate, or main state) were slow (15–45 ms); those between the residual state and a substate or the main state were fast (1–2 ms). Under steady-state conditions, the open channel probability, Po, decreased in a sigmoidal manner from 1 to 0 (Boltzmann fit: Vj,o = -44 mV; z = 6). The temperature coefficient, Q10, for gamma j(main state) and gamma j(residual state) was 1.2 and 1.3, respectively (p < 0.001; range 15–40 degrees C). This difference suggests interactions between ions and channel structure in case of gamma j(residual state). In cell pairs with many channels, the gap junction conductance at steady state, gj, exhibited a bell-shaped dependency from Vj (Boltzmann fit, negative Vj, Vj,o = -45 mV, gj(min) = 0.24; positive Vj, Vj,o = 49 mV, gj(min) = 0.26; z = 6). We conclude that each channel is controlled by two types of gates, a fast one responsible for Vj gating and involving transitions between open states (i.e., residual state, substates, main state), and a slow one involving transitions between the closed state and an open state.
Published: 1995
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4. Ablation of connexin30 in transgenic mice alters expression patterns of connexin26 and connexin32 in glial cells and leptomeninges

Author: B D, Lynn, O, Tress, D, May, K, Willecke, and J I, Nagy
Subjects: Mice, Knockout, Brain, Fluorescent Antibody Technique, Gap Junctions, Mice, Transgenic, Connexins, Connexin 26, Mice, Inbred C57BL, Mice, Meninges, Connexin 30, Animals, Humans, Neuroglia
Abstract: Expression of connexin26 (Cx26), Cx30 and Cx43 in astrocytes and expression of Cx29, Cx32 and Cx47 in oligodendrocytes of adult rodent brain has been well documented, as has the interdependence of connexin expression patterns of macroglial cells in Cx32- and Cx47-knockout mice. To investigate this interdependence further, we examined immunofluorescence labelling of glial connexins in transgenic Cx30 null mice. Ablation of astrocytic Cx30, confirmed by the absence of immunolabelling for this connexin in all brain regions, resulted in the loss of its coupling partner Cx32 on the oligodendrocyte side of astrocyte-oligodendrocyte (A/O) gap junctions, but had no effect on the localization of astrocytic Cx43 and oligodendrocytic Cx47 at these junctions or on the distribution of Cx32 along myelinated fibres. Surprisingly, gene deletion of Cx30 led to the near total elimination of immunofluorescence labelling for Cx26 in all leptomeningeal tissues covering brain surfaces as well as in astrocytes of brain parenchyma. Moreover northern blot analysis revealed downregulation of Cx26 mRNA in Cx30-knockout brains. Our results support earlier observations on the interdependency of Cx30/Cx32 targeting to A/O gap junctions and further suggest that Cx26 mRNA expression is affected by Cx30 gene expression. In addition, Cx30 protein may be required for co-stabilization of gap junctions or for co-trafficking in cells.
Published: 2011

5. Immunofluorescent Localization of a Connexin 26‐like Protein at the Surface of Mesophyll Protoplasts from Vicia faba L. and Helianthus annuus L

Author: Margot Schulz, Mona Knop, Heide Schnabl, K. Willecke, and O. Traub
Subjects: fungi, Immunocytochemistry, food and beverages, Connexin, Plant Science, Plasmodesma, Protoplast, Biology, Vicia faba, Biochemistry, Polyclonal antibodies, Plant protein, Helianthus annuus, biology.protein
Abstract: Mesophyll protoplasts from three week old leaves of Helianthus annuus L. and from four week old leaves of Vicia faba L. were incubated with polyclonal, monospecific antibodies, raised against either cx 32 or cx 26 mouse liver connexin. Crossreactions were visualized by FITC-labeled anti-rabbit antibodies. Incubations with the cx 26 antibody resulted in fluorescing spots on protoplast surfaces of both plant species, indicating the presence of a polypeptide, immunologically related to the animal cx 26. A plant protein, exhibiting similarities to cx 26, would present a new member of connexin-like plant proteins. Controls, performed with preimmune serum or with the FITC-conjugate alone, were negative. Immunofluorescing spots were not obtained after incubations with the cx 32 antibody. Since the existence of a cx 32-like plant protein, associated with ultrastructures of plasmodesmata and the plasma membrane, is meanwhile established, several explanations for the failed attempt to demonstrate a cx 32 antibody labeling at protoplast surfaces are discussed.
Published: 1992
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6. Immunological Evidence of Connexin‐like Proteins in the Plasma Membrane of Vicia faba L

Author: K. Willecke, Carola Hunte, O. Traub, Margot Schulz, and Heide Schnabl
Subjects: biology, Biochemistry, Membrane protein, Plant protein, Polyclonal antibodies, biology.protein, Plant Science, Antibody, Membrane transport, Protoplast, Immunostaining, Vicia faba
Abstract: Plasma membranes from three week old leaves of Vicia faba L. were enriched by aqueous two-phase partitioning to high purity. Plasma membrane proteins were immunoblotted with polyclonal, monospecific antibodies raised against mouse liver connexins (cx) 32 and 26. Immunostaining after treatments with cx 32 antibodies revealed the existence of a 29 kDa protein, clearly enriched in the plasma membrane fraction. An additional immunoreactive band of 20 kDa, possibly a degradation product of the 29 kDa protein, was found in the soluble fraction. When immunoblots were incubated with cx 26 antibodies, a 40 kDa band with a strong immunoresponse appeared, assumed to present the dimeric form of a 21 kDa, cx 26-like plant protein. The monomeric form could be only obtained when intact leaf material or mesophyll protoplasts from three week old plants were directly SDS-extracted. Furthermore, in young, one week old leaves, the monomer seems to exist in larger amounts, together with another crossreacting 35 kDa protein. The 29 kDa (cx 32-related) as well as the 40 kDa (cx 26-related) polypeptide is obviously located in the plasma membrane. The 40 kDa protein has to be considered as a new connexin-like plant protein.
Published: 1992
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7. BIOLOGICAL FUNCTIONS OF GAP JUNCTION CHANNELS REVEALED BY TARGETED CONNEXIN DEFICIENT MICE

Author: T. Ott and K. Willecke
Subjects: Chemistry, Gap junction, Deficient mouse, Connexin, Cell biology
Published: 2003
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8. Transfection and expression of exogenous connexins in mammalian cells

Author: D, Manthey and K, Willecke
Subjects: Genetic Vectors, Cell Culture Techniques, Animals, Gene Expression, Humans, Indicators and Reagents, Blotting, Northern, Fluorescent Antibody Technique, Indirect, Transfection, Connexins, HeLa Cells
Published: 2001

9. Lack of phenobarbital-mediated promotion of hepatocarcinogenesis in connexin32-null mice

Author: O, Moennikes, A, Buchmann, A, Romualdi, T, Ott, J, Werringloer, K, Willecke, and M, Schwarz
Subjects: Male, Mice, Inbred C3H, Cocarcinogenesis, Drug Synergism, Organ Size, Connexins, Mice, Inbred C57BL, Mice, Liver Neoplasms, Experimental, Liver, Phenobarbital, Carcinogens, Animals, Diethylnitrosamine, Female, Precancerous Conditions, Crosses, Genetic
Abstract: Connexin32 (Cx32) is the major gap junction forming protein in liver. We have recently shown that hepatocarcinogenesis is strongly enhanced in mice deficient in Cx32, demonstrating that lack of functional Cx32 accelerates liver tumorigenesis. Many tumor-promoting agents, including phenobarbital, block gap junctional intercellular communication in vitro, and it has been suggested that this effect is relevant for clonal expansion of neoplastic cells in vivo. We have now tested this hypothesis by analyzing the potency of phenobarbital as a liver tumor promoter in male Cx32-wild-type (Cx32(Y/+)) and Cx32-null (Cx32(Y/-)) mice. Preneoplastic and neoplastic liver lesions were induced in 6-week-old male mice by a single injection of 90 microg/g body weight of N-nitrosodiethylamine, and groups of mice were subsequently kept on phenobarbital-containing (0.05%) or control diet for 39 weeks. Frozen liver sections were prepared, and (pre)neoplastic lesions were identified by their deficiency in glucose-6-phosphatase staining. In addition, the number and size of macroscopically visible tumors were monitored. Phenobarbital led to a approximately 5-fold increase in the volume fraction occupied by glucose-6-phosphatase-deficient liver lesions in Cx32(Y/+) mice, whereas there was no such increase in Cx32(Y/-) mice. Even more pronounced differences were observed with respect to tumor response. Whereas phenobarbital clearly promoted the occurrence of numerous large hepatomas in Cx32(Y/+) mice, no such effect was seen in Cx32(Y/-) mice. These results demonstrate, for the first time, that functional Cx32 protein is required for tumor promotion by phenobarbital.
Published: 2000

10. Biological functions of connexin genes revealed by human genetic defects, dominant negative approaches and targeted deletions in the mouse

Author: K, Willecke, S, Kirchhoff, A, Plum, A, Temme, E, Thönnissen, and T, Ott
Subjects: Connexin 26, Mice, Mutagenesis, Connexin 43, Gene Targeting, Genetic Diseases, Inborn, Animals, Humans, Connexins
Abstract: Gap junction channels in mammalian organs can be built up of at least 13 different connexin proteins, most of which are expressed in only few cell types, although many cells express more than one connexin protein. Recently, the consequences of missing or defective connexin proteins were studied in human patients with defects in connexin32 (Cx32; beta 1; X-linked Charcot-Marie-Tooth disease) or in Cx26 (beta 2; non-syndromic sensorineural deafness), and in mice with targeted deletions in the Cx26, Cx32, Cx37 (alpha 4), Cx43 (alpha 1), Cx46 (alpha 3) or Cx50 (alpha 8) genes. Some effects of dominant negative mutations in connexin genes have been characterized in Xenopus oocytes and transfected mammalian cells in culture. Here we review results of these different experimental approaches and report new findings regarding the characterization of Cx40 (alpha 5)- and Cx31 (beta 3)-deficient mice. The phenotypic alterations, caused by different defective connexin genes in mice or humans, are divergent, although in most known cases the viability is not affected. When more than one connexin gene, coexpressed in the same cell, is inactivated, development or maturation can be more severely affected at an earlier stage. Some connexin proteins, if present in the same cell, can partially replace each other in certain functions. Thus, the diversity of connexin proteins in mammalian cells may provide functional overlap and complementation.
Published: 1999

11. Doubly mutant mice, deficient in connexin32 and -43, show normal prenatal development of organs where the two gap junction proteins are expressed in the same cells

Author: F D, Houghton, E, Thönnissen, G M, Kidder, C C, Naus, K, Willecke, and E, Winterhager
Subjects: Male, Thyroid Gland, Gene Expression, Tooth Germ, Extremities, Connexins, Embryonic and Fetal Development, Mice, Connexin 43, Mutation, Animals, Odontogenesis, Female, Alleles, Crosses, Genetic
Abstract: The connexins are a family of proteins that form the intercellular membrane channels of gap junctions. Genes encoding 13 different rodent connexins have been cloned and characterized to date. Connexins vary both in their distribution among adult cell types and in the properties of the channels that they form. In order to explore the functional significance of connexin diversity, several mouse connexin-encoding genes have been disrupted by homologous recombination in embryonic stem cells. Although those experiments have illuminated specific physiological roles for individual connexins, the results have also raised the possibility that connexins may functionally compensate for one another in cells where they are coexpressed. In the present study, we have tested this hypothesis by interbreeding mice carrying null mutations in the genes (Gjb1 and Gja1) encoding connexin32 (beta 1 connexin) and connexin43 (alpha 1 connexin), respectively. We found that fetuses lacking both connexins survive to term but, as expected, the pups die soon thereafter from the cardiac abnormality caused by the absence of connexin43. A survey of the major organ systems of the doubly mutant fetuses, including the thyroid gland, developing teeth, and limbs where these two connexins are coexpressed, failed to reveal any morphological abnormalities not already seen in connexin43 deficient fetuses. Furthermore, the production of thyroxine by doubly mutant thyroids was confirmed by immunocytochemistry. We conclude that, at least as far as the prenatal period is concerned, the normal development of those three organs in fetuses lacking connexin43 cannot simply be explained by the additional presence of connexin32 and vice-versa. Either gap junctional coupling is dispensable in embryonic and fetal cells in which these two connexins are coexpressed, or coupling is provided by yet another connexin when both are absent.
Published: 1999

12. Connexin 32 gap junctions enhance stimulation of glucose output by glucagon and noradrenaline in mouse liver

Author: F, Stümpel, T, Ott, K, Willecke, and K, Jungermann
Subjects: Mice, Norepinephrine, Glucose, Liver, Portal Vein, Reference Values, Injections, Intravenous, Animals, Gap Junctions, Glucagon, Connexins, Mice, Mutant Strains
Abstract: Gap junctions connect neighboring cells via intercellular channels composed of connexins (Cx). Connexin 32 (Cx32) is the main connexin in hepatocytes. Gap junctions propagate a signal from periportal to perivenous hepatocytes generated by electrical stimulation of sympathetic liver nerves. Therefore, it was the aim of this study to examine the involvement of hepatocellular gap junctions in hormonal regulation. In perfused livers from wild-type mice and Cx32-deficient mice, the stimulation of glucose release by varying noradrenaline and glucagon concentrations was investigated. At saturating hormone concentrations, glucose release was the same in wild-type and Cx32-deficient livers. However, glucose output was significantly smaller in Cx32-deficient than wild-type livers at half-maximally effective hormone concentrations. Because the two hormones circulate at less than half-saturating concentrations and because they are degraded during passage of blood through the liver, they lose efficiency from the periportal to the perivenous zone. In wild-type livers, this decrease in efficiency can be partially compensated by intercellular signal propagation through gap junctions, resulting in higher hormone actions than in Cx32-deficient livers. It is concluded that gap junctions are not only involved in intercellular propagation of nervous, but also of hormonal signals from periportal to perivenous hepatocytes.
Published: 1998

13. Connexin32-null mice develop demyelinating peripheral neuropathy

Author: S S, Scherer, Y T, Xu, E, Nelles, K, Fischbeck, K, Willecke, and L J, Bone
Subjects: Central Nervous System, Male, Mice, Knockout, Aging, Heterozygote, Peripheral Nervous System Diseases, Immunohistochemistry, Connexins, Mice, Microscopy, Electron, Animals, Female, Schwann Cells, Myelin Sheath, Demyelinating Diseases
Abstract: Mutations in the gene encoding the gap junction protein connexin32 (Cx32) cause X-linked Charcot-Marie-Tooth disease (CMTX), a common form of inherited demyelinating peripheral neuropathy. To learn more about the pathogenesis of CMTX, we examined the PNS and CNS of cx32-null mice (cx32-/Y males and cx32-/-females) by light and electron microscopy. These mice develop a progressive demyelinating peripheral neuropathy beginning by 3 months of age, and at all ages, motor fibers are more affected than sensory fibers. Like other genes of the X chromosome, the cx32 gene appears to be randomly inactivated, since only some myelinating Schwann cells express Cx32 in heterozygous cx32 +/- females. Heterozygous cx32 +/- females have fewer demyelinated and remyelinated axons than age-matched homozygous cx32-/- females and cx32-/Y males. Although oligodendrocytes also express Cx32, no abnormalities in CNS myelin were found. These findings indicate that a null cx32 allele in myelinating Schwann cells is sufficient to cause an inherited demyelinating neuropathy, so that Cx32 has an essential role in myelinating Schwann cells both in mice and in humans.
Published: 1998

14. Advances in Charcot-Marie-Tooth disease research: cellular function of CMT-related proteins, transgenic animal models, and pathomechanisms. The European CMT Consortium

Author: H W, Müller, U, Suter, C, Van Broeckhoven, C O, Hanemann, E, Nelis, V, Timmerman, S, Sancho, L, Barrio, P, Bolhuis, R, Dermietzel, M, Frank, A, Gabreëls-Festen, C, Gillen, N, Haites, G, Levi, E, Mariman, R, Martini, K, Nave, B, Rautenstrauss, M, Schachner, A, Schenone, C, Schneider, M, Schröder, K, Willecke, and O, Haneman
Subjects: Animals, Genetically Modified, Disease Models, Animal, Neurology, Charcot-Marie-Tooth Disease, Research, Animals, Humans, Nerve Tissue Proteins
Abstract: The First Workshop of the European Consortium on Charcot-Marie-Tooth (CMT) disease brought together neuroscientists, molecular and cell biologists, neuropathologists, neurologists, and geneticists with a common interest in the understanding of the fundamental mechanisms that underlie the pathogenesis of CMT. The interdisciplinary group of 25 expert scientists discussed recent advances in (i) molecular genetics and histopathology of CMT, (ii) development of suitable animal models, (iii) understanding of the cellular function of CMT-related proteins, and (iv) studies using nerve biopsies from CMT patients. In this minireview, we summarize the key findings presented and discuss their impact on CMT research.
Published: 1997

15. Coexpression of connexin45 and -32 in oligodendrocytes of rat brain

Author: P, Kunzelmann, I, Blümcke, O, Traub, R, Dermietzel, and K, Willecke
Subjects: Oligodendroglia, Animals, Newborn, Astrocytes, Animals, Brain, Gap Junctions, Rats, Wistar, Antibodies, Cells, Cultured, Connexins, Rats
Abstract: Connexin proteins are the subunits of gap junction channels, and are encoded by a gene family. Although several connexin mRNAs were detected in brain, only a few connexin-proteins have been localized to specific cell types in this tissue. Here we describe expression of connexin45 protein in oligodendrocytes in rat hippocampus. Double immunofluorescent staining using specific antibodies to connexin45 and connexin32 paired with cell-type specific marker proteins revealed that connexin45 and connexin32 were co-expressed and colocalized in oligodendrocytes. Each of the connexin antibodies gave rise to the same pattern of punctate fluorescence in the plasma membrane of cell bodies and proximal processes of oligodendrocytes. Connexins in the plasma membrane of oligodendrocytes may form gap junctions between oligodendrocytes, or between oligodendrocytes and astrocytes. Expression of connexin45 in oligodendrocytes may prevent dysmyelinating effects of connexin32 mutations in the central nervous system of Charcot-Marie-Tooth (X-type) patients.
Published: 1997

16. A second alternative transcript of the gap junction gene connexin32 is expressed in murine Schwann cells and modulated in injured sciatic nerve

Author: G, Söhl, C, Gillen, F, Bosse, M, Gleichmann, H W, Müller, and K, Willecke
Subjects: Male, DNA, Complementary, Base Sequence, Molecular Sequence Data, Single-Strand Specific DNA and RNA Endonucleases, Gap Junctions, Gene Expression, Exons, Sciatic Nerve, Connexins, Introns, Rats, Mice, Animals, Newborn, Sequence Homology, Nucleic Acid, Animals, Schwann Cells, Cloning, Molecular, Rats, Wistar, Promoter Regions, Genetic, Sequence Analysis, Cells, Cultured, DNA Primers, Gene Library
Abstract: Four connexin32 (Cx32) cDNA clones isolated from a rat sciatic nerve cDNA library differ in the nucleotide sequence of their 5' untranslated region (UTR) from the corresponding Cx32 cDNA clones previously characterized from liver. The new Cx32 5'UTR sequence detected in the sciatic nerve cDNA clones is identical to one previously found in the 6.5 kb intron of the murine Cx32 gene. Using primer extension and S1 nuclease protection analysis, we determined the transcriptional starting point of this new alternative Cx32 transcript expressed in the sciatic nerve. This starting point is located 444 bp (409 bp) upstream of exon2 in a region previously described as an intron of the Cx32 gene in the rat (and mouse) genome, respectively. The alternative exon1B comprises 99 bp in rat, but 97 bp in the mouse genome, and is spliced to the same exon2 acceptor site also used for splicing of exon1 in liver. Both transcripts are likely to code for the same Cx32 protein whose reading frame is located in exon2. The putative promoter region, upstream of the alternative exon1B, contains a TATAAA motif and has been sequenced and noticed before by Miller et al. (Biosci. Rep. 8, 455-464, (1988)). The alternative exon1B transcript is highly expressed in the sciatic nerve, (i.e. Schwann cells) and very low in liver (i.e. hepatocytes). Its expression is regulated after sciatic nerve injury. The time course of expression was similar to previously established myelin genes and, therefore, we suggest that the expression of the alternative exon1B Cx32 transcript is related to the process of myelination. Very recently, we have characterized another alternative Cx32 exon1A which is transcribed in mouse embryonic stem cells but not in the sciatic nerve (Dahl et al., submitted for publication, 1995). Thus, the murine Cx32 gene is likely to be regulated by three alternative promoters that appear to be activated in a cell type-specific manner.
Published: 1996

17. Negative growth control of HeLa cells by connexin genes: connexin species specificity

Author: M, Mesnil, V, Krutovskikh, C, Piccoli, C, Elfgang, O, Traub, K, Willecke, and H, Yamasaki
Subjects: DNA, Complementary, Transcription, Genetic, Blotting, Western, Transplantation, Heterologous, Gap Junctions, Mice, Nude, Cell Communication, Neoplasms, Experimental, Isoquinolines, Transfection, Connexins, Mice, Species Specificity, Animals, Humans, Cell Division, HeLa Cells
Abstract: In order to examine whether different connexin gene species exert different degrees of tumor-suppressing activity, we characterized growth characteristics of a gap junction-deficient human cancer cell line, HeLa cells, before and after transfection with cDNA for three different connexins, connexin (cx) 26, cx 40, and cx 43. All transfected cell lines (3 clones transfected with the cx 26 gene, 2 clones with cx 40, and 1 with cx 43) showed establishment of gap junctional intercellular communication (GJIC). Two of the cx 26-transfected clones showed significantly slower growth compared with the parental HeLa cells. When transfectants were grown in soft agar, the three cx 26-transfected clones grew much less than the other transfectants and parent HeLa cells. When injected into nude mice, the two cx 26 clones which exhibited the highest amount of cx 26 transcript induced almost no tumors, whereas other transfectants, including the cx 26 clone which exhibited the lowest amount of cx 26 transcript, were tumorigenic. Among transfectants of various connexin genes, there was no good inverse correlation between their GJIC and tumorigenicity. GJIC levels were significantly higher in tumors induced in nude mice by clone cx 26 A and E transfectants. These results suggest that all of the connexin genes examined could induce recovery of GJIC of HeLa cells, but only the cx 26 gene exerts strong negative growth control on HeLa cells; thus, this connexin gene may have different functions from other connexin genes.
Published: 1995

18. Immunochemical characterization of connexin31, −37, −40, −43, and −45 in cultured primary cells, transfected cell lines and murine tissues

Author: Birgit Hertlein, U. Gergs, K. Willecke, B. Hafemann, K. Balzer, Otto Traub, A. Butterweck, and C. Elfgang
Subjects: Chemistry, Cell culture, Transfection, Primary cell, Molecular biology
Published: 1995
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19. Differential expression of the gap junction proteins connexin45, -43, -40, -31, and -26 in mouse skin

Author: A, Butterweck, C, Elfgang, K, Willecke, and O, Traub
Subjects: Keratinocytes, Mice, Inbred C3H, Recombinant Fusion Proteins, Blotting, Western, Fluorescent Antibody Technique, Blotting, Northern, Transfection, Connexins, Cell Line, Connexin 26, Mice, Animals, Humans, Hair, HeLa Cells, Skin
Abstract: The expression of five different members of the gap junction multigene family, connexin (Cx)45, -43, -40, -31, and -26 was investigated in embryonic and adult mouse skin. For this purpose, polyclonal antibodies to Cx31 and Cx45 were raised by immunizing rabbits with fusion proteins of glutathione S-transferase and carboxy-terminal peptides including 65 amino acids of Cx31 or 138 c-terminal amino acids of Cx45, respectively. Here we describe characterization of the affinity-purified Cx31 antibodies in human HeLa cells, transfected with mouse Cx31 coding DNA, and in mouse keratinocyte-derived cell lines. In the epidermis of embryonic mice at day 19 of gestation Cx43 and -45 were detected in the basal layer, while the stratum spinosum showed expression of Cx43, -31 and -26. In the stratum granulosum we found expression of Cx31 and -26. In the epidermis of adult mice Cx43 and -31 were located similarly as in embryonic tissue, but Cx45 as well as Cx26 were not detected and in addition Cx40 was weakly expressed in the stratum basale. Furthermore, during hair development, Cx31 was detected in the inner epithelial root sheath and sebaceous glands of hair follicle. Cx43 and -40 were found in the outer epithelial root sheath and to a lesser extent in sebaceous glands. Cx31 was also demonstrated in Hel-37 and Hel-30, i.e. two related cell lines derived from mouse keratinocytes. Our results show that epidermal and follicular differentiation coincides with differential expression of five different connexin proteins, suggesting specific and coordinated function(s) of gap junctional communication during skin and hair development.
Published: 1994

20. Functional identification and molecular cloning of a rat gene mediating growth inhibition and programmed cell death in normal and transformed rat cell lines

Author: I, Schwarte-Waldhoff, W, Martin, K, Willecke, and R, Schäfer
Subjects: Oncogene Protein gp140(v-fms), Retroviridae Proteins, Oncogenic, Drug Resistance, Apoptosis, Neomycin, DNA, Oncogenes, Protein-Tyrosine Kinases, Transfection, Cell Line, Oncogene Proteins v-raf, Rats, Genes, ras, Phenotype, Animals, Cloning, Molecular, Cell Division, Cell Line, Transformed
Abstract: We wished to identify DNA sequences conferring suppression of proliferation and transformed phenotypes. Thus, we have transfected DNA from normal rat cells, covalently linked to neo DNA coding for neomycin resistance into a tumorigenic, HRAS transformed rat cell line. Phenotypic revertants were selected after the first cycle of transfection by enrichment procedures that served to eliminate transformed cells. The revertant clones continued to express the HRAS oncogene, but exhibited a lower tumorigenicity, loss of anchorage-independent proliferation, flat morphology, and retardation of growth in monolayer culture. The reverted phenotype could be transferred in a second cycle of transfection into the HRAS transformed rat cells. Neo DNA ligated to genomic donor DNA was used as a tagging sequence to molecularly clone the transferred DNA sequence in a recombinant phage. Fragments of the cloned DNA detect a 2.5 kb transcript in parental cells and revertants. Thus, the recombinant phage harbors a putative growth inhibitory gene, designated trg, that is expressed at a higher level in rat embryo fibroblasts and in the REF52 cell line. Introduction of recombinant phage DNA into established 208F and Rat-2 cells and into HRAS-, v-fgr-, v-fms- and v-raf-transformed rat cell lines resulted in inhibition of growth and induction of programmed cell death.
Published: 1994

21. Two gap junction genes, connexin 31.1 and 30.3, are closely linked on mouse chromosome 4 and preferentially expressed in skin

Author: H, Hennemann, E, Dahl, J B, White, H J, Schwarz, P A, Lalley, S, Chang, B J, Nicholson, and K, Willecke
Subjects: Transcription, Genetic, Genetic Linkage, Xenopus, Molecular Sequence Data, Restriction Mapping, Gene Expression, Hybrid Cells, Connexins, Mice, Cricetulus, Cricetinae, Skin Physiological Phenomena, Animals, Amino Acid Sequence, RNA, Messenger, Cloning, Molecular, Gene Library, Genome, Base Sequence, Chromosome Mapping, Membrane Proteins, DNA, Blotting, Southern, Liver, Karyotyping, Multigene Family, Oocytes
Abstract: Two new gap junction genes isolated from the mouse genome code for connexin homologues of 271 and 266 amino acids, designated here Cx31.1 and Cx30.3, respectively. The two open reading frames, oriented in the same direction, are only 3.4 kb apart on mouse chromosome 4. Within the connexin family, these two proteins are most closely related to one another (70% amino acid sequence identity) and to Cx31 (65 and 68% identity, respectively). Comparison of the Cx31.1 mouse gene with a Cx31.1 cDNA showed a similar genomic organization to that found with other members of the connexin gene family, i.e. the coding and 3'-untranslated regions are contained within a single exon, which is preceded by an intron, less than 25 bases upstream of the ATG start codon. Northern blot hybridization revealed highly tissue-specific coexpression of the 1.6-kb Cx31.1 mRNA and two Cx30.3 transcripts of 1.9- and 3.2-kb size, predominantly in skin and two related mouse keratinocyte cell lines. Minor levels of Cx31.1 mRNA were detected in testis. Microinjection of Cx30.3, but not Cx31.1 cRNA, into Xenopus oocyte pairs induced formation of functional gap junction channels with unique voltage-gated parameters compared to other connexins expressed similarly.
Published: 1992

22. Molecular cloning of mouse connexins26 and -32: similar genomic organization but distinct promoter sequences of two gap junction genes

Author: H, Hennemann, G, Kozjek, E, Dahl, B, Nicholson, and K, Willecke
Subjects: Binding Sites, Base Sequence, Transcription, Genetic, Molecular Sequence Data, Restriction Mapping, Membrane Proteins, Blotting, Northern, Connexins, Mice, Gene Expression Regulation, Liver, Oligodeoxyribonucleotides, Animals, Amino Acid Sequence, Cloning, Molecular, Promoter Regions, Genetic, Skin
Abstract: Connexins26 and -32 are subunit proteins of gap junctions that are coexpressed in hepatocytes and several tissues but individually expressed in other cells. Molecular cloning of both corresponding mouse genes revealed similar genomic organization, i.e., each gene consists of two exons with the complete coding region located in the second exon. The first exon of each gene is preceded by a TATA-less promoter region. The promoter of the mouse Cx26 gene has at least two transcription start sites and is located in a very GC-rich region which is reminiscent of promoters of house-keeping genes. Putative consensus sequences for a metal response element, the transcription factor NFkappaB, and several GC-boxes were found within 600 bp upstream of the Cx26 transcription start sites. The promoter region of the mouse Cx32 gene contains two putative binding sites for the transcription factor HNF-1 and consensus motifs for NF-1 as well as NFkappaB within 680 bp upstream of the main transcription start site. Thus the sequence comparison of mouse Cx26 and Cx32 promoter regions provides hints for possible consensus elements that could control individual expression as well as common regulation of these gap junction genes in various tissues. Cx26 mRNA is much more abundant in adult mouse skin than in adult kidney and liver where Cx32 transcripts are relatively strongly expressed.
Published: 1992

23. Characterization of gap junction genes expressed in F9 embryonic carcinoma cells: molecular cloning of mouse connexin31 and -45 cDNAs

Author: H, Hennemann, H J, Schwarz, and K, Willecke
Subjects: Base Sequence, Transcription, Genetic, Molecular Sequence Data, Membrane Proteins, Cell Differentiation, Blotting, Northern, Connexins, Blotting, Southern, Mice, Intercellular Junctions, Tumor Cells, Cultured, Animals, Amino Acid Sequence, RNA, Messenger, Cloning, Molecular, Gene Library
Abstract: In an attempt to characterize connexin genes expressed early in mouse development we screened a cDNA library from mouse F9 embryonic carcinoma cells with mouse connexin37 cDNA and mouse connexin31.1 genomic DNA under low stringency of hybridization. We detected 5 different connexin cDNAs coding for mouse connexins31, -31.1, -32, -43, and -45 (reviewed in Willecke et al., Eur. J. Cell Biol. 56, 1-7 (1991)). Here we describe characterization of mouse connexin31 cDNA coding for a protein of 270 amino acids (Mr 30,905) that shows 8 amino acid exchanges compared to its rat analog recently deduced from its genomic sequence. Mouse connexin45 cDNA codes for a protein of 396 amino acids (Mr 45,671) that exhibits 84% amino acid identity compared to its chick analog described. Cx31 and Cx45 are coded for by single genes in the mouse genome. After Northern blot hybridization, we detected two Cx31 transcripts of 1.9 and 2.3 kb in total mouse RNA from skin, keratinocyte-derived cell lines, and in testis. Cx45 cDNA hybridized to a 2.2 kb mRNA in lung, brain, skin, heart, and intestine. This transcript showed maximal expression in adult lung and in embryonic tissues tested (brain, skin, kidney) where it was at least 40-fold more abundant than in the corresponding adult tissues.
Published: 1992

24. The diversity of connexin genes encoding gap junctional proteins

Author: K, Willecke, H, Hennemann, E, Dahl, S, Jungbluth, and R, Heynkes
Subjects: Mice, Intercellular Junctions, Protein Conformation, Sequence Homology, Nucleic Acid, Molecular Sequence Data, Animals, Genetic Variation, Membrane Proteins, Amino Acid Sequence, Connexins
Abstract: The multigene family of connexins is larger than previously anticipated. Ten different connexin homologous sequences have been characterized in the mouse genome, five of which are probably the mouse analogues of the known rat connexins26, -31, -32, -43, and -46. Since the additional 5 sequences have been isolated as cDNAs or hybridize specifically to distinct mRNA species, they most likely represent functional connexin genes. Since seven of the genomic connexin sequences have been shown to contain no intron in the coding sequence, this may apply to all mammalian connexin genes. Some of the structural features based on amino acid sequences deduced from cDNA or genomic sequences and the RNA expression pattern of the new connexins are compared with previously described connexins. The structural diversity of the connexin genes suggests that they fulfill different functions coordinated with, and perhaps required for, different programs of cellular differentiation.
Published: 1991

25. Growth inhibition of oncogene-transformed rat fibroblasts by cocultured normal cells: relevance of metabolic cooperation mediated by gap junctions

Author: W, Martin, G, Zempel, D, Hülser, and K, Willecke
Subjects: Cell Communication, Oncogenes, Fibroblasts, Cell Line, Rats, Cell Transformation, Neoplastic, Intercellular Junctions, Neoplasms, Carbenoxolone, Cell Adhesion, Animals, Cell Division, Cells, Cultured, Plasmids
Abstract: We have studied the proliferation of rat 208F cells (a derivative of Rat-1 cells) transformed by activated c-Ha-ras, v-fgr, v-raf, v-fms, or v-src oncogenes during cocultivation with an excess of early passage rat embryonic fibroblasts or immortal 208F cells. The total number and size of foci formed by oncogene-transformed 208F cells were strongly reduced by cocultured normal fibroblasts. The extent of growth suppression of transformed foci appears to be dependent on the type of transforming oncogene and on the type of normal fibroblasts rather than on the extent of gap-junctional communication between transformed and normal cells. Total inhibition of fluorescent dye transfer between normal and transformed cells by the 3 beta-O-hemisuccinate of 18 alpha-glycyrrhetinic acid (18 alpha-carbenoxolone), an inhibitor of gap-junctional communication in human fibroblasts, did not prevent growth inhibition of transformed cells in the cocultivation assay. Since adjacent cells remained electrically coupled in the presence of this inhibitor it is possible that the strongly reduced metabolic cooperation, as indicated by the lack of fluorescent dye transfer, is sufficient for mediating the growth-inhibitory effect of normal fibroblasts. 208F cell-conditioned medium, however, also caused strong growth inhibition of transformed derivatives, suggesting that the effect is in part mediated by release of stable growth inhibitor(s) from 208F cells.
Published: 1991

26. Expression of different connexin genes in rat uterus during decidualization and at term

Author: E, Winterhager, R, Stutenkemper, O, Traub, E, Beyer, and K, Willecke
Subjects: Uterus, Gene Expression, Membrane Proteins, Rats, Inbred Strains, Blotting, Northern, Immunohistochemistry, Connexins, Rats, Estrus, Pregnancy, Decidua, Myometrium, Animals, Female
Abstract: The expression of different connexin genes (cx26, cx32, cx37, cx43) that code for the protein subunits of gap junctions, was investigated in various uterine tissues during the estrous cycle of nonpregnant rats, in pregnant rats at decidualization and at term. Connexin gene expression was studied at the mRNA level by Northern blot hybridization and at the protein level by immunocytochemistry. In gap junctions from uterine epithelium, stroma, or myometrium, connexin 26 and/or connexin 43 are much more abundant than connexins 32 and 37. The expression of connexin 26 and 43 appears to be modulated by maternal steroid hormones. High expression of these connexins is found in developing decidual cells by day 7 to 8 post coitum; furthermore, coexpression of connexins 26 and 43 in myometrium is observed just before delivery on day 21 post coitum. In both the decidua and the myometrium, the connexin 26 protein appears to be distributed in lower abundance than connexin 43. In uterine epithelium only connexin 26 is expressed throughout all of the reproductive phases investigated. The enhanced expression of this gene correlates with higher levels of maternal estrogen both in the proestrus/estrus phase and at term. The distinct spatial and temporal pattern of expression of connexins 26 and 43 in different uterine tissues suggests a physiological role for these proteins during embryo implantation and subsequent contraction of the uterus at birth.
Published: 1991

27. Six genes of the human connexin gene family coding for gap junctional proteins are assigned to four different human chromosomes

Author: K, Willecke, S, Jungbluth, E, Dahl, H, Hennemann, R, Heynkes, and K H, Grzeschik
Subjects: Blotting, Southern, X Chromosome, Chromosomes, Human, Pair 13, Chromosomes, Human, Pair 1, Multigene Family, Chromosome Mapping, Humans, Membrane Proteins, Chromosomes, Human, Pair 6, Connexins
Abstract: Connexin genes code for proteins that form cell-to-cell channels known as gap junctions. The genes for the known connexins 26, 32, 43, and 46 have been assigned to human chromosomes, 13, X, 6, and 13, respectively, by analysis of a panel of human-mouse somatic cell hybrids using rat cDNA probes. A pseudogene of connexin 43 that lacks an intron of the cx43 gene has been located on human chromosome 5. Furthermore, the genes of the two new connexins 37 and 40 have both been assigned to human chromosome 1. Thus the human chromosomes 1 and 13 each carry at least two different connexin genes. Their exact location on these chromosomes is not yet known. From our results subchromosomal assignments can be deduced for the human cx32 gene to Xq13-p11, the human cx37 gene as well as the human cx40 gene to 1pter-q12, and the human cx43 gene to 6q14-qter. The generation of the connexin multigene family from a hypothetical ancestral connexin gene is discussed.
Published: 1990

28. Altered expression of proto-oncogenes in human lymphoid cells immortalized by transfection with extrachromosomal DNA of mouse L cells

Author: H, Abken, C, Bützler, and K, Willecke
Subjects: Cell Transformation, Neoplastic, L Cells, Phenotype, Proto-Oncogenes, Gene Amplification, Gene Expression, Humans, Lymphocytes, RNA, Messenger, Transfection, Proto-Oncogene Mas, Cell Line, Transformed
Abstract: Human lymphocytes were induced to proliferate continuously in vitro by transfection with extrachromosomal DNA from mouse L929 cytoplasts. The immortalized cells contain 2- to 5-fold increased mRNA levels of only 3 (c-Ha-ras-1, c-Ki-ras, c-myc) out of 18 proto-oncogenes tested compared to quiescent lymphocytes. Furthermore, the immortalized cells contain decreased amounts of c-fos mRNA, 2- to 20-fold decreased amounts of lck and c-fgr mRNA and 10-fold increased levels of JD15 mRNA compared to primary lymphocytes. The immortalised cells do not harbor amplified copies or any major rearrangement of these genes. No additional copy of these genes transferred from the mouse genome could be detected in the immortalized human cell lines. Thus, the changes in the level of these proto-oncogene transcripts in the lymphoid cells are likely to be induced by the immortalizing DNA from L929 cytoplasts and appear to be associated with continuous proliferation of these cells. Since the immortalized cell lines do not form colonies in soft agar medium and do not induce tumors in nude mice, we suggest that the altered expression of these proto-oncogenes may be due to the transition from quiescent to continuous proliferation in vitro ("immortalization"), but does not correlate with a tumorigenic phenotype of the cells.
Published: 1990

29. Buchbesprechung

Author: K. Willecke
Subjects: Drug Discovery, Molecular Medicine, General Medicine, Genetics (clinical)
Published: 1991
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30. Absract

Author: Marietta Kaszkin, Volker Kinzel, Karl Maly, Irina Bichler, Florian Lang, Hans H. Grunicke, R. Pepperkok, R. Jakobi, P. Lorenz, W. Ansorge, W. Pyerin, P. Borowski, M. Harbers, A. Ludwig, T. Kischel, H. Hilz, K. Eckert, A. Granetzny, J. Fischer, R. Grosse, V. Manch, S. Wehner, B. Kornhuber, U. Ebener, K. Müller-Decker, G. Fürstenberger, I. Vogt, F. Marks, G. Graschew, A. Küsel, W. Hull, W. Lorenz, H. W. Thielmann, Gisela H. Degen, Alexius Freyberger, A. Müller, M. Linscheid, Ulrike Hindermeier, Ute Jorritsma, K. Golka, W. Föllmann, H. Peter, H. M. Bolt, S. Monnerjahn, D. N. Phillips, A. Never, A. Seidel, A. R. Glatt, K. Wiench, E. Frei, P. Schroth, M. Wiessler, T. Schäfer, M. Hergenhahn, E. Hecker, D. Proft, P. Bartholmes, R. S. Bagewadikar, B. Bertram, N. Frank, Hanno Leibersperger, Michael Gschwendt, Friedrich Marks, S. Fasco, Peter Plein, Karin Schiess, Lothar Seidler, T. Jacobi, E. Besemfelder, M. Stephan, W. D. Lehmann, M. Grell, B. Thoma, P. Scheurich, Markus Meyer, Hans Grunicke, G. Jaques, B. Wegmann, K. Ravemann, Odilia Popanda, Heinz Walter Thielmann, H. Voss, U. Wirkner, Dieter Werner, D. Strand, A. Kalmes, H. -P. Walther, B. Mechler, S. Volker Schirrmacher, V. Kinzel, R. Hess, H. -G. Hanagarth, C. Hässler, G. Brandner, Christian Ertel, B. Gückel, V. Schirrmacher, B. A. Kyewski, U. Bogdahn, P. Jachimczak, J. Schneider, W. Brysch, W. Schlingensiepen, D. Drenkard, C. Behl, J. Winkler, R. Apfel, J. Meixensberger, K. Stulle, P. Marquardt, H. P. Vollmers, J. Müller, H. -K. Müller-Hermelink, M. Schuermann, G. Seemann, Angelika Ptok, M. Ptok, T. E. Carey, M. Steffen, U. C. Nitz, B. Everding, F. Hölzel, G. Kantwerk-Funke, G. Boll, K. S. Zänker, P. Hölzel, J. Heymanns, C. Hennig, M. Rotsch, K. Havemann, Jürgen R. Fischer, Sabine Stehr, Harald Lahm, Peter Drings, Peter H. Krammer, M. Kirsch, A. Strubel, A. Kist, R. Hinn, H. Fischer, A. Buttler, G. Schackert, S. Friedenauer, D. Lindner, B. Marczynski, H. Karcls, H. W. Goergens, B. Epe, E. Müller, D. Schütze, S. Boiteux, E. Eder, C. Deininger, C. Hoffman, E. Scherer, E. Vermeulen, H. J. van Kranen, J. Bax, R. A. Woutersen, C. F. van Kreijl, B. Schurich, H. Hagedorn, E. Kamp, G. Eisenbrand, B. Spiegelhalder, U. Bolm-Audorff, H. G. Bienfait, R. Preussmann, C. -D. Wacker, H. Kehl, Z. Akkan, J. Ries, M. Meger, S. E. Shephard, D. Gunz, W. K. Lutz, A. R. Tricker, R. Kurnar, M. Siddiqi, P. Mende, B. Pfundstein, A. Scholl, C. Janzowski, D. Jacob, P. Goelzer, I. Henn, H. Zankl, K. -H. Zimlich, Barbara Gansewendt, Ricarda Thier, K. R. Schroeder, E. Hallier, G. Moeckel, W. Heiden, M. Waldherr-Teschner, J. Brickmann, H. Roeser, G. Krauter, G. Scherer, A. Krätschmer, H. Hauenstein, F. Adlkofer, R. C. Fernando, H. H. Schmeiser, W. Nicklas, Wolfgang Pfau, David H. Phillips, S. Scheckenbach, S. Cantoreggi, Monika Leutbecher, H. Ottenwälder, U. Föst, P. M. Baumgart, H. -C. Kliem, S. Data, C. Pfeiffer, A. Fuchs, P. Schmezer, F. Kuchenmeister, B. L. Pool-Zober, U. M. Liegibel, B. L. Pool-Zobel, L. Steeb, H. Friesel, Th. Schneider, H. R. Scherf, A. Buchmann, R. Bauer-Hofmann, J. Mahr, M. Schwarz, R. Schmidt, F. Rippmann, B. Steinbauer, P. Zlfu, B. Bunk, W. Hefter, K. Klinga, M. R. Berger, L. W. Robertson, G. Luebeck, S. Moolgavkar, U. Torsten, M. Kowalczyk-Wagner, H. Weitzel, Ch. Zechel, H. Peters, F. Anders, S. Ambs, T. Kirchner, H. -G. Neumann, C. Einig, E. Eigenbrodt, D. Oesterle, E. Deml, G. Weisse, U. Gerbracht, H. Stumpf, E. Filsingcr, P. Bannasch, W. Muster, P. Cikryt, P. Münzel, E. Röhrdanz, K. W. Bock, H. -P. Lipp, T. Wiesmüller, H. Hagenmaier, D. Schrenk, A. Karger, G. Bauer, P. Höfler, M. Götschl, E. Viesel, J. Jürgensmeier, D. Schaefer, G. Picht, J. Kiefer, P. Krieg, R. Schnapke, S. Feil, E. Wagner, U. Schleenbecker, A. Anders, M. M. Gross, S. Unger, E. J. Stanbridge, Petra Boukamp, Ulrich Pascheberg, Norbert E. Fusenig, H. Abken, U. H. Weidle, F. Grummt, K. Willecke, R. Schäfer, A. Hajnal, I. Balmer, R. Klemenz, P. E. Goretzki, H. Reishaus, M. Demeure, H. Haubruck, J. Lyons, H. D. Röher, Sylvia Trouliaris, Angelika Hadwiger-Fangmeier, Elke Simon, Heiner Niemann, Teruko Tamura, G. Westphal, Elke Turner, H. Karels, M. Blaszkewicz, Helga Stopper, Dietmar Schiffmann, Umberto De Boni, M. Schuler, R. Schnitzler, M. Metzler, E. Pfeiffer, R. Aulenbacher, T. Langhof, K. R. Schröder, K. Saal, H. K. Müller-Hermelink, W. Henn, G. Seitz, P. Lagoda, A. Christmann, N. Blin, C. Welter, D. Adam, D. Fömzler, C. Winkler, W. Mäueler, M. Schartl, B. Theisinger, G. Schüder, U. Rüther, C. Nunnensiek, H. A. G. Müller, W. Rupp, M. Lüthgens, P. Jipp, I. Kinzler, M. Gulich, H. J. Seidel, O. H. Clark, F. McCormick, H. R. Bourne, F. Gieseler, F. Boege, H. Biersack, B. Spohn, M. Clark, K. Wilms, Fritz Boege, Frank Gieseler, Harald Biersack, Michael Clark, Klaus Wllms, Axel Polack, Lothar Strobl, Regina Feederle, Matthias Schweizer, Dirk Eick, Georg W. Bornkamm, M. Kopun, H. Scherthan, C. Granzow, P. Janiaud, D. Rueß, B. M. Mechler, P. G. Strauss, V. Erfle, M. Fritsche, C. Haessler, H. Christiansen, J. Schestag, N. M. Christiansen, F. Lampert, Wolfgang A. Schulz, Andreas Hasse, Helmut Sies, G. Orend, I. Kuhlmann, W. Doerfler, A. Behn-Krappa, I. Hölker, U. Sandaradura de Silva, Ute Smola, Dagmar Hennig, Angelika Hadviger-Fangmeier, Burkhard Schütz, R. Kerler, H. M. Rabes, G. Dölken, A. A. Fauser, R. Kerkert, U. Ragoczy, R. Fritzen, W. Lange, J. Finke, B. Nowicki, E. Schalipp, W. Siegert, R. Mertelsmann, U. Schilling, H. J. Sinn, W. Maier-Borst, E. A. Friedrich, E. Löhde, M. Lück, H. Raude, H. Schlicker, G. Barzen, E. Kraas, J. Milleck, R. Keymer, S. Störkel, T. Reichert, F. Steinbach, R. Lippold, W. Thoenes, W. Wagner, K. -A. Reiffen, A. Bardosi, D. Brkovic, H. -J. Gabius, B. Brandt, C. Jackisch, D. Seitzer, M. Hillebrand, F. A. Habermann, null Zeindl-Eberhart, null Evelyn, C. Robl, V. Röttgen, C. Nowak, H. -B. Richter-Reichhelm, V. Waldmann, B. Suchy, Ch. Zietz, M. Sarafoff, Richard Ostermayr, Hartmut M. Rabes, J. Lorenz, T. Friedberg, W. Paulus, R. Ferlinz, F. Oesch, E. Jähde, K. -H. Glüsenkamp, L. F. Tietze, M. F. Rajewsky, G. Chen, K. -J. Hutter, J. Bullerdiek, W. J. Zeller, M. Schirner, M. R. Schneider, P. Zbu, M. Gebelein, B. Naser-Hijazi, Nancy E. Hynes, M. Reinhardt, P. Heyl, D. Schmähl, P. Presek, U. Liebenhoff, D. Findik, G. H. Hartmann, C. Kliesch, F. Albert, S. Kunze, M. Wannnenmacher, J. Boese-Landgraf, E. Lorenz, D. Albrecht, M. Dulce, K. R. Aigner, N. Thiem, H. Müller, M. Leonardi, A. Justh, M. Lutz, E. Lang, C. W. v. d. Lieth, H. Sinn, B. R. Betsch, Jan Georg Hengstler, Jürgen Fuchs, Franz Oesch, F. J. Busch, A. B. C. Cato, G. Schied, W. Tang, B. Richter, C. Schaefer, D. K. Kelleher, P. Vaupel, D. Mundt, H. H. Bartsch, H. Meden, M. Meyer, K. Vehmeyer, R. Mull, W. Kuhn, S. Hoffmann, D. Berger, H. Fiebig, Ch. Moog, B. Luu, S. Frühauf, B. K. Keppler, A. Galeano, P. Valenzuela-Paz, T. Klenner, H. Stadler, G. Golomb, E. Breuer, R. Voegeli, P. Hilgard, H. R. Nowrousian, P. Aulenbacher, B. Winterhalter, C. Granson, M. Stöhr, H. Ponstingl, P. Drings, H. Osswald, S. B. Sobottka, E. Amtmann, G. Sauer, B. Hornung, S. Volland, S. Kahl, R. Gerspach, B. Matz, J. Schmidt, M. Lipp, G. Brehm, A. Luz, S. Wendel, P. G. Strauß, V. Erflte, S. Greehmann, A. Zobel, F. Kalkbrenner, G. Vorbrüggen, K. Moelling, T. Iftner, A. H. Müller, P. G. Fuchs, H. Pfister, Klaus Cichutek, Iris Treinies, Matthias Lang, C. Braun, J. Denner, S. Norley, R. Kurth, L. Music, O. D. Wiestler, A. Aguzzi, A. von Deimling, M. Schneemann, R. Elbl, P. Kleihues, H. Land, H. -P. Hohn, M. Höök, H. -W. Denker, W. Kemmner, K. Zaar, Peter A. Jones, R. Kath, M. Herlyn, P. Maier, H. P. Schawalder, J. Elsner, W. Parzefall, E. Erber, R. Sedivy, R. Schulte-Hermann, J. Hemmer, P. Tomakidi, P. Boukamp, D. Breitkreutz, N. E. Fusenig, F. Kallinowski, W. Strauss, A. L. Brownell, I. D. Bassukas, G. Vester, B. Maurer-Schultze, L. Langbein, H. Kosmehl, D. Katenkamp, Eberhard Spiess, Günther Trefz, Werner Ebert, Peter Jordan, Dieter Kübler, Rosemarie B. Lichtner, Marion Wiedemuth, Annette Kittmann, Axel Ullrich, Khashayarsha Khazaie, Aiga Kowitz, Guni Kadmon, Peter Altevogt, U. H. Frixen, J. Behrens, J. Schipper, M. Sachs, H. Birchmeier, R. Hackenberg, Th. Hawighorst, J. Hofmann, H. Beato, K. -D. Schulz, C. Erbil, M. Maasberg, L. A. Kunz, A. Simm, G. Adam, W. Mueller-Klieser, Andreas M. Kaufmann, Michael Stoeck, A. Hülsen, S. Game, M. Donnelly, H. -J. Stark, K. -H. Schlingensiepen, U. Kurzik-Dumke, B. Phannavong, D. Gundacker, E. Gateff, S. Gabius, S. S. Joshi, H. Franz, N. J. John, R. Grümmer, H. W. Denker, M. W. Gross, and U. Karbach
Subjects: Cancer Research, Oncology, General Medicine
Published: 1991
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31. Human mitochondrial thymidine kinase is coded for by a gene on chromosome 16 of the nucleus

Author: Frank H. Ruddle, Raju Kucherlapati, T Teber, and K. Willecke
Subjects: Protein Conformation, Adenine phosphoribosyltransferase, Chromosome Mapping, Karyotype, General Medicine, Hybrid Cells, Biology, Thymidine Kinase, Isozyme, Molecular biology, Mitochondria, Chromosome 17 (human), MT-TK, Chromosome 16, Genes, Thymidine kinase, Genetics, Humans, Electrophoresis, Polyacrylamide Gel, Gene, Chromosomes, Human, 16-18
Abstract: The expression of human mitochondrial thymidine kinase (mt TK) was investigated by polyacrylamide electrophoresis in 19 independent human-mouse somatic cell hybrids which allowed all human chromosomes to be analyzed. In 8 hybrid clones the presence of this enzymatic activity could be demonstrated. Human mt TK segregated concordantly with human adenine phosphoribosyltransferase (APRT) and human chromosome 16. Discordant segregation with all other human chromosomes was demonstrated by karyotype and isozyme analyses. These results suggest that human mt TK is coded for by a gene on chromosome 16 of the nucleus. Thus human mt TK is genetically different from human cytosol thymidine kinase which is coded for by a gene on chromosome 17. The appearance of one heteropolymer band after electrophoretic separation of human and murine mt TK supports the notion that both enzymes have dimeric structures.
Published: 1977
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32. Contents, Vol. 22, 1978

Author: N.E. Morton, P. Pierce, K. Simola, C.E. Wright, E.J. Yunis, M.E. Chandler, H. Vriesendorp, B.J.B. Keats, C.J. Sherr, K. Bender, R.E. Magenis, H. Oie, B.B. Knowles, J.M. Luciani, M.P. Cowmeadow, I.L. Hansteen, M. Bobrow, G.A. Koch, M. Prensky, P.A. Lalley, N. Shimizu, E.A. Nichols, J. Garver, K. Hirschhorn, A. Brøgger, A.F. Gazdar, S. Hempfling, L.C. Yu, B. Pernis, R. Mausner, S. Leupe-de Smit, R.C.P. Go, A. Westerveld, L. R. Weitkamp, K.E. Toomey, D. Borgaonkar, S. Piomelli, D. Bootsma, T. Campana, E.W. Lovrien, O.J. Miller, H.J. Cooke, F.T. Kao, D.A. Aitken, S. Burgess, L.L. Haley, Y. Boyd, A. Mayerová, T.B. Shows, H.J. Evans, J. Fraisse, K.-H. Grzeschik, V.M. Regina, K.C. Atwood, L.M.M. Wijnen, Liao Law, H.-H. Ropers, M.A. Ferguson-Smith, M.A. Pellegrino, T. Gedde-Dahl, V.A. McKusick, A.C. Leary, J. H. Olving, M.G. Byers, D. Swallow, K.M. Overton, W.F. Witterland, J. Hemmerling, S.J. Funderburk, A. de la Chapelle, N.R. Mendell, U. Francke, Veronica van Heyningen, A.F. Naylor, I.W. Craig, A. Heiberg, R.S. Lemons, J.E. Gray, E. Herbschleb-Voogt, J.J. Yunis, D.B. Amos, C.K. Eun, J.L. Hamerton, L. U. Lamm, N. Oliver, S. Goodnight, F. Pellett, T.M. Dijksman, J.M. Vance, R.E. Eisenman, P. Rubinstein, A. Bratlie, G.A.P. Bruns, V. Kirton, R. Roos, D.L. Slate, M.C. Yoshida, D.L. George, R.C. Schwartz, K.E. Buckton, A.S. Henderson, R. Jonassen, J.A. Robinson, P.L. Pearson, M. Hultén, E. Solomon, A.E. Greene, L.Y. Wang, R. Lange, S. Brown, M.L. Schroeder, P. Karli, A. Krüger, J.M. Robert, B. Lauras, J. Chamberlin, A. Shalev, J. Ott, B.J. Mintz, Elizabeth B. Robson, Per Teisberg, N. Tanigaki, P. M. Conneally, S. Rosenfeld, A.S. Baim, M.L. Rivas, J.A. Brown, R. Johannsmann, N. Suciu-Foca, R. Mierau, T.T. Puck, C.G. Palmer, S.J. Jeremiah, D. Warburton, M. Devictor-Vuillet, J.A. Norton, T. Ho, J.E. Noades, F. Varricchio, E.H.Y. Chu, B. Carritt, R. Schwab, I. Balazs, J. Reiss, C.N. Fear, S. Povey, Erik Thorsby, A. Siverts, D.W. Ball, W. Stanley, L.R. Weitkamp, M.E. Duncan, C. Jones, K. Willecke, S. Philipps, R. Moreland, D.C. Rao, E. Tolley, T. Philip, E. Johnston, M. Monteba-van Heuvel, A.D. Merritt, T.H. Roderick, R.L. Eddy, S. Arias, R.A. Fisher, M.A. Craft, J.H. Edwards, M.C. Sparkes, N.C. Sun, L. Korsnes, D.A. Meyers, M.Y. Tsai, A.W. Johnston, A. Estop, B.M. Turner, K. Berg, S. Guttormsen, W.G. Burgerhout, A.P. Goggin, T. Mohandas, W.K. Stanford, C.W. Bazinet, M. Siniscalco, R.H. Lindenbaum, H.P. Klinger, W.S. Volkers, J. Gavin, K.K. Namboodiri, M.T. Davisson, P.J. McAlpine, W.R.T. Los, M. Meisler, L.J. Donald, F.H. Ruddle, W. Bauch, Timothy A. Donlon, C.R.Y. Sun, R. Bigley, R.S. Sparkes, H. Kaita, P.S. Gerald, E.R. Giblett, I. Berczi, R.C. Elston, S.J. O’Brien, C.T. Falk, L. Scrafford-Wolff, M. Smith, M.K. Fagerhol, J. de Witt, S. Rowe, D. Cox, E.S. Seravalli, T. Borun, M. Lewis, R. Saisson, M.A. Pericak-Vance, R.T. Taggart, R.D.G. McKay, M. Mota, W. R. Mayr, Matthew Parks, F. Freycon, Y. Shimizu, B. Hellkuhl, D.P. Aden, C.A. Slaughter, J.E. Anderson, E. Lovrien, R.M. Denney, N. Lamvik, J. Parekh, B.P. Dorman, A.P.M. Jongsma, M.A. Nijman, C. Verma, J. Wood, M.J. Champion, R. Sanger, A. Bennick, P.L. Yu, A.F. Wilson, W.L. Marsh, L. Pajunen, H. Hameister, B.A. Doppert, J.J. Garver, J.R. Sawyer, P. Meera Khan, P.J.L. Cook, Bjørnar Olaisen, R.C. Karn, J.D. Minna, J.D. Shulkin, B.M. Page, P.M. Sinet, B. Sykes, E.M. Helveston, C.W.H. Partridge, M. Blumenthal, P. Szabo, and E.A. Azen
Subjects: Botany, Genetics, Biology, Molecular Biology, Genetics (clinical)
Published: 1978
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33. Human oncogenes

Author: K, Willecke and R, Schäfer
Subjects: Genes, Viral, Turkey, Gene Amplification, Oncogenes, Cell Transformation, Viral, Translocation, Genetic, Cell Line, Rats, Mice, Tumor Virus Infections, Cell Transformation, Neoplastic, Retroviridae, Cebidae, Neoplasms, Mutation, Carcinogens, Cats, Genetics, Animals, Humans, Virus Activation, Chickens, Genetics (clinical)
Abstract: The information published on human oncogenes up to the fall of 1983 is reviewed. Retroviral oncogenes, proto-oncogenes, and cellular transforming genes are compared. Transforming genes derived from the ras gene family are described in detail. The different mechanisms of activation of proto-oncogenes are summarized. Finally, the concerted or sequential action of cellular transforming genes in the multi-step process of carcinogenesis is discussed.
Published: 1984
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34. Assignment of the gene for galactokinase to human chromosome 17 and its regional localisation to band q21-22

Author: Raju Kucherlapati, E.A. Nichols, Richard E. Giles, Frank H. Ruddle, K. Willecke, R.P. Creagan, S.M. Elsevier, and J.K. McDougall
Subjects: Genetics, Multidisciplinary, Phosphotransferases, Somatic Cell Genetics, Chromosome Mapping, Chromosome, Hybrid Cells, Biology, Galactokinase, Cell Line, Clone Cells, Chromosome 17 (human), Leloir pathway, Mice, Genes, Thymidine kinase, Animals, Humans, Human genome, Gene, Chromosomes, Human, 16-18
Abstract: PROGRESS in somatic cell genetics now allows more rapid and precise localisation of genes within the human genome. A large number of mouse × human hybrid cell lines are available, permitting the investigator to choose, for phenotype assay, lines with a particular reduced human chromosome complement. An increasingly large number of hybrid lines carrying rearranged chromosomes are also becoming available for regional localisation studies. We have used such hybrid cell lines to assign a gene coding for galactokinase (EC 2.7.1.6) to human chromosome 17 and to further localise the gene to band 21–22 on the long arm of the chromosome. Results from this study have provided new information Regarding the functioning of the genes coding for the Leloir pathway enzymes in man1, and have revealed a relatively close and potentially useful linkage between the genes for galactokinase and for thymidine kinase (EC 2.7.1.21).
Published: 1974
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35. Simultaneous light and electron microscopic observation of immunolabeled liver 27 KD gap junction protein on ultra-thin cryosections

Author: B Yancey, R Dermietzel, O Traub, K Willecke, Jean-Paul Revel, and U. Janssen-Timmen
Subjects: Pathology, medicine.medical_specialty, Histology, Immunocytochemistry, Fluorescent Antibody Technique, Immunologic Tests, Immunofluorescence, Connexins, Connexon, law.invention, Immunolabeling, law, medicine, Animals, Frozen Sections, Frozen section procedure, medicine.diagnostic_test, biology, Histocytochemistry, Gap junction, Antibodies, Monoclonal, Membrane Proteins, Rats, Microscopy, Electron, Intercellular Junctions, Liver, Polyclonal antibodies, biology.protein, Biophysics, Gold, Anatomy, Electron microscope
Abstract: We report on immunolabeling of gap junction protein in rat liver. Simultaneous light and electron microscopic immunolabeling of ultra-thin frozen sections was performed to confirm that the antigenic targets of polyclonal antibodies and a monoclonal 27 KD antibody (12/1 C5) are the gap junctions. Our results clearly demonstrate that the immunoreactive sites determined by indirect immunofluorescence correspond to immunogold-labeled gap junctions identified in the same section according to electron microscopic criteria. Our results also support the concept that the 27 KD protein is a major constituent of gap junctions.
Published: 1987
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36. Unstable transformation of mouse 3T3 cells by transfection with DNA from normal human lymphocytes

Author: R. Schäfer, K. Willecke, S. Griegel, and M.A. Dubbert
Subjects: Time Factors, Biology, Transfection, General Biochemistry, Genetics and Molecular Biology, Cell Line, Restriction fragment, Mice, chemistry.chemical_compound, Cell Adhesion, Animals, Humans, Neoplastic transformation, Lymphocytes, Molecular Biology, Gene, Repetitive Sequences, Nucleic Acid, General Immunology and Microbiology, General Neuroscience, Molecular biology, Transformation (genetics), Cell Transformation, Neoplastic, chemistry, Cell culture, biology.protein, Cell Division, DNA, Research Article, Transformation efficiency
Abstract: DNA fragments (0.5-4.5 kb) of normal human lymphocytes induced pre-neoplastic mouse NIH/3T3 cells after transfection to grow in soft agar medium at low efficiency (0.0007 colonies/micrograms DNA/10(6) cells). In secondary transfections high mol. wt. DNA (greater than 20 kb) of cells transformed by DNA fragments induced neoplastic transformation with high efficiency (0.16-1.1 soft agar colonies/micrograms DNA/10(6) cells). These results confirm previous data obtained by others with chicken and mouse donor DNA. We describe here that independent secondary transformants harbored human Alu repetitive DNA sequences on similar restriction fragments and formed progressively growing tumors in BALB/c mice or nude mice. The corresponding primary transformants were not tumorigenic, however, and the ability to proliferate in semi-solid agar medium was gradually lost when the cells were grown as non-confluent monolayers. Furthermore, in contrast to secondary transformants, DNA from primary transformants showed only relatively weak hybridization to a human Alu repetitive DNA probe. We conclude that in primary transformants the transformed phenotype is expressed in an unstable fashion whereas secondary transformants appear to be stably transformed.
Published: 1984
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37. Immunocytochemical localization of the gap junction 26 K protein in mouse liver plasma membranes

Author: R. Dermietzel, K. Willecke, U. Janssen-Timmen, A. Leibstein, O. Traub, and U. Frixen
Subjects: Immunoelectron microscopy, Cell, Biology, Antibodies, Connexins, General Biochemistry, Genetics and Molecular Biology, Mice, medicine, Animals, Binding site, Molecular Biology, Mice, Inbred BALB C, General Immunology and Microbiology, General Neuroscience, Vesicle, Cell Membrane, Gap junction, Microtomy, Immunohistochemistry, Molecular biology, Connexin 26, medicine.anatomical_structure, Membrane, Liver, Microscopy, Fluorescence, Cytoplasm, biology.protein, Rabbits, Antibody, Research Article
Abstract: Specific binding sites for anti-26 K antibodies directed against the liver gap junction protein (26 K) were localized by immunoelectron microscopy in gap junction plaques purified from hepatic plasma membranes. Using immunofluorescence microscopy we found discrete fluorescent spots on plasma membranes in cross sections of liver tissues after incubation with anti-26 K antibodies. This is consistent with the notion of specific binding to gap junction plaques. Quantitative binding of anti-26 K antibodies was indirectly measured by the protein A-gold technique. We found that urea/detergent-treated, purified gap junction plaques bind 30-fold more anti-26 K antibodies than preimmune serum. Anti-26 K antibodies also bind specifically to native gap junction plaques within hepatic plasma membranes although only about one fifth as efficiently as to purified plaques. Possibly the anti-26 K antibodies raised after injection of SDS-denatured 26 K protein into rabbits recognize the cytoplasmic face of urea/detergent-treated plaques better than that of native plaques. Some, if not most, of the vesicular structures in preparations of purified plaques appear to be derived from split gap junction plaques and are probably sheets of gap junction hemichannels. In some vesicles the former cytoplasmic face of the hemichannels is turned outside, other vesicles have the former cell surface turned outside. The anti-26 K antibodies do not recognize any 26 K protein on the sheets of partially split gap junction plaques, on the heterogeneous vesicular structures, or on non-junctional areas of hepatic plasma membranes. These results suggest that the conformation of the 26 K protein in plaques must be different from that of the 26 K protein in earlier biosynthetic steps of plaque assembly.
Published: 1983
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38. Transforming Activity of DNA Fragments from Normal Human Lymphocytes Results from Spontaneous Activation of a c-Ha-ras1 Gene

Author: O Traub, S Geisse, I Schwarte, S Griegel, Reinhold Schäfer, and K. Willecke
Subjects: Proto-Oncogenes, Chromosome Mapping, DNA, Oncogenes, Cell Biology, Transfection, Biology, Dna rearrangements, Molecular biology, Mice, chemistry.chemical_compound, Residue (chemistry), Cell Transformation, Neoplastic, chemistry, Animals, Humans, Spontaneous mutation, Deoxyguanosine, Lymphocytes, Molecular Biology, Gene, Research Article
Abstract: An activated human Ha-ras gene was present in a secondary NIH 3T3 transformant isolated after serial transfection of originally low-molecular-weight DNA fragments from normal human cells. This gene appeared to have acquired its transforming properties by a spontaneous mutation in codon 12 by substitution of a deoxythymidine residue for a deoxyguanosine residue. DNA rearrangements in the flanking sequences of the transferred Ha-ras gene were not involved in the activation of the protooncogene.
Published: 1985
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39. Subject Index Vol. 16, 1976

Author: D.E. Wilson, P. Shaffer-Berman, E. Solomon, N. Shimizu, S. Goss, P. DeBona, A.G. Steinberg, R.M. Siervogel, A.S. Henderson, T.-S. Chan, J.E. Anderson, A.B. Deisseroth, J.A. Anderson, D. Weil, A.D. Merritt, M. Velivasakis, D. Cox, P. Meera Khan, K.M. Overton, G.B. Côté, E. Lovrien, J.A. Brown, S. Chen, C. Finaz, R.H. Schwartz, I.W. Craig, J. Courval, B. Olaisen, P. Teisberg, J.A. Robinson, P.L. Pearson, M.C. DuVal, N. Busby, M. Ray, T.P. Webb, R.H. Kennett, C.J. Chern, P.J. Davies, I. Schreuder, B. Kaiser McCaw, H. Wyandt, J. Mohr, A. Icén, K.E. Buckton, A.R. Dunn, A.W. Nienhuis, J.V. Higgins, R.G. Worton, P.J.L. Cook, G. Spowart, J.A. Norton, J.E. Noades, R.S. Kucherlapati, W.S. Volkers, T.B. Shows, H. Wang, R.A. Raeburn, Matthew Parks, R.E. Magenis, M. Bobrow, S. Hansen, H.M. Dick, S.H. Boyer, S.H. Hsu, Veronica van Heyningen, K.R.M. Pai, R.A. Fisher, D.P. Aden, C.A. Slaughter, A.B. Bijnen, R.D. Koler, S. Guttormsen, R. Sanger, D. Linder, F. Hecht, D. Bacon, R.B. Surana, P.L. Yu, L.A. Klobutcher, O. Smithies, T.T. Puck, D.A. Hopkinson, D. Warburton, D. Shaw, K. Berg, S.J. Goss, L.L.L. Wijnen, D.A. Meyers, A. Heiberg, T. Gedde-Dahl, E. Hackel, C. Cochet, J. Frézal, C.M. Giles, A.A. Biegel, I.P. Gormley, M. Smith, F.-T. Kao, P. Vuopio, B. Schacter, B. Clark, J.D. Minna, T.A. Tedesco, M.G. Brown, C.J. Glueck, K.G. Orkwiszewski, H. Skre, K. Hirschhorn, N. Van Cong, W.F. Bodmer, W.G. Burgerhout, B.A. Doppert, W. Bodmer, G. Skude, A. Boué, E.A. Jones, K.C. Atwood, S. McDonald, C.M. Croce, E. Eicher, E.S. Seravalli, R.C.P. Go, C.G. Palmer, E.B. Robson, K. Bender, D.A. Aitken, R.P. Creagan, W.F. Anderson, P.H. Gallimore, J.B. Dossetor, W. Putt, M. Lewis, V. Lewis, F.H. Ruddle, J. Ott, H. Eiberg, M. Rivas, T.H. Marshall, M.E. Hodes, K.D. Smith, P. Bowen, A.P.M. Jongsma, R. Bigley, N. Lea, G.F. Brooks, H. Kaita, L. Wisniewski, E.R. Giblett, H.E. Faber, R.C. Elston, P. Couillin, W.B. Bias, H. Koprowski, R. Rebourcet, C.T. Falk, M.T. Yu, L.J. Stevens, U. Francke, J.J. van Rood, G. Pontecorvo, P.E. Polani, D. Patterson, E.W. Lovrien, E.A. Nichols, J.L. Hamerton, D.P. Singal, J.K. McDougall, M.L. Rivas, T. Reber, B.H. Petersen, S. Povey, Erik Thorsby, G. Khoury, E. Tolley, W.R. Breg, T. Hassold, L. Kunkel, R.L. Eddy, L.L. Haley, J. Shuster, M.A. Ferguson-Smith, D.W. Buck, R.M. Denney, K. Lange, F.H. Allen, B.R. Migeon, P. Goodfellow, R. Kucherlapati, L.R. Weitkamp, J. de Grouchy, B.M. Turner, S.S. Wachtel, T. Mohandas, P.M. Conneally, M. Siniscalco, M.D. Poulik, R. Velez, A. Hershberg, B. Moore, G.C. Koo, V.M. Chapman, A. Westerveld, B. Hellkuhl, H.P. Klinger, D. Bootsma, K.K. Namboodiri, G. Wullems, O.J. Miller, P. Gold, P. Perry, P.J. McAlpine, P.A. Lalley, A. Brøgger, J. Schlaut, M.W. Thompson, A. de la Chapelle, B. Chown, A.G. Searle, I. Pagan-Charry, C. Jones, J. van der Horst, H. van Someren, K. Willecke, E. Johnston, J.H. Edwards, W.J. Mellman, K.-H. Grzeschik, S. Ohno, P. Teesdale, C.S.N. Lee, L. Wang, and V.S. Turner
Subjects: Index (economics), Statistics, Genetics, Subject (documents), Biology, Molecular Biology, Genetics (clinical)
Published: 1976
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40. Chromosomal gene transfer: prospects of a new method for mapping closely linked human genes

Author: T. Reber, K. Willecke, and P.J. Davies
Subjects: Genetics, Genetic Linkage, Chromosome Mapping, Gene transfer, Biology, ENCODE, Transformation, Genetic, Genes, Methods, Animals, Humans, Human genome, Molecular Biology, Genetics (clinical)
Published: 1976
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41. Contents, Vol. 14, 1975

Author: T. Gedde-Dahl, P.M Conneally, G.R. Douglas, J. Prosser, E. Grace, J.L. Hamerton, K.-H. Grzeschik, M.A. Ferguson-Smith, P.L. Pearson, G. Corneo, E.A. Nichols, G.J. Wullems, M. Bobrow, N.C. Sun, J.E. Syrett, J.K. McDougall, R. Rebourcet, J. Frézal, V.A. McKusick, F.H. Ruddle, W. Keijzer, A. Westerveld, T.G. Gedde-Dahl, R.M. Baker, R.C. Miller, F. Hecht, P. Goodfellow, B. Olaisen, J. Ott, A.J.J. Reuser, A. Vust, C.W.H. Partridge, D.R. Bolling, J. Fleming, S.E. Gardiner, P.J. McAlpine, D.M. Steffensen, E.R. Giblett, D. Kacian, E.M. Wurzer-Figurelli, R.S. Kucherlapati, T.B. Shows, K. Berg, H. Bosker, K.C. Atwood, M.C. Rattazzi, D.W. Buck, K.W. Jones, A.G.J.M. van der Linden, R.P. Clayton, J. German, W. Prensky, V. Niewczas-Late, D. Bergsma, C.M. Giles, D.A. Meyers, E.M. Eicher, D.S. Borgaonkar, D. Mutton, K.P. Glen, P.M. Ellis, K. Hirschhorn, E. Jones, S. Povey, A. Hoogeveen, J. van der Horst, J.J. van Rood, P.M. Price, B. Bengtsson, W.G. Burgerhout, C.C. Chang, L.R. Weitkamp, R.E. Giles, E. Magenis, H. van Someren, H.M.A. Beyersbergen van Henegouwen, R.A. Buckland, K. Willecke, U. Francke, D. Bootsma, C. Partridge, R. Kennett, E. Johnston, D.A. Hopkinson, A.E. Greene, O. Mutchinick, R.P. Creagan, R.S.K. Chaganti, L. Komarnicki, T. Mohandas, M. Fellous, K. Fenger, J.H. Edwards, G. Beckman, A.S. Henderson, M.L. Rivas, L. Beckman, W.R.T. Los, L.L. Coriell, I. Purdom, N. van Cong, P. Meera Khan, H.A. de Wit-Verbeek, G.B. Côté, A.R. Mitchell, Veronica van Heyningen, S.A. Sørensen, L. Wang, E. Solomon, J.A. Brown, W.S. Volkers, H. Galjaard, J.E. Anderson, C. Pangalos, A.P.M. Jongsma, R. Sanger, S.M. Elsevier, E. Lovrien, A.B. Bijnen, M.K. Fagerhol, J.A. Pierce, M. Lewis, E.H.Y. Chu, W.B. Bias, D. Weil, S. Chen, J. de Wit, C.G. Palmer, P.W. Teesdale, F.A. McMorris, G. Miller, A.D. Merritt, R.G. Davidson, J.R. Gosden, I. Schreuder, W.F. Bodmer, P.J.L. Cook, J.E. Gray, N. Busby, H. Kaita, R.C. Elston, Y.-S. Teng, S.M. Bowser Riley, R.A. Oosterbaan, P.L. Townes, E.B. Robson, H.J. Evans, L.E. Nijenhuis, and A. Hagemeijer
Subjects: Botany, Genetics, Biology, Molecular Biology, Genetics (clinical)
Published: 1975
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42. Differential expression of three gap junction proteins in developing and mature brain tissues

Author: K. Willecke, Rolf Dermietzel, T. K. Hwang, David C. Spray, O. Traub, Eric C. Beyer, and Michael V. L. Bennett
Subjects: Aging, Ependymal Cell, Connexin, Biology, Connexins, Embryonic and Fetal Development, Mice, Pineal gland, otorhinolaryngologic diseases, medicine, Animals, education, Mice, Inbred BALB C, education.field_of_study, Multidisciplinary, Gap junction, Brain, Membrane Proteins, Rats, Inbred Strains, Immunohistochemistry, Embryonic stem cell, Rats, Cell biology, Neuroepithelial cell, medicine.anatomical_structure, Membrane protein, Organ Specificity, Immunology, Connexin 32, sense organs, Research Article
Abstract: By using antibodies directed against gap junction proteins of liver (connexins 26 and 32) and heart (connexin 43), we have localized immunoreactivity to specific cell types in frozen sections of adult rodent brains. Connexin 32 reactivity was found in oligodendrocytes and also in a few neurons, whereas reactivity to connexins 26 and 43 was localized to leptomeningeal cells, ependymal cells, and pineal gland. Immunoreactivity with antibodies to connexin 43 also occurred in astrocytes. Furthermore, during embryonic and postnatal maturation of brain tissues, gap junction proteins were differentially expressed. Connexins 43 and 26 predominated in the neuroepithelium of embryonic brains, whereas connexin 32 was virtually absent. Between 3 and 6 weeks after birth, connexin 26 largely disappeared from immature brain; this time course corresponded to the increased expression of connexin 32. Expression of connexin 43 remained high throughout embryonic and postnatal development. These findings demonstrate that gap junction expression in the brain is diverse, with specific cell types expressing different connexins; this cell-specific distribution may imply differences in the function of these intercellular channels in different loci and developmental stages.
Published: 1989
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43. Subject Index Vol. 22, 1978

Author: S.J. Funderburk, J.E. Gray, G.A. Koch, L. Korsnes, A.S. Henderson, W.R.T. Los, D.A. Meyers, J.D. Minna, Per Teisberg, J.D. Shulkin, B.M. Page, M.C. Yoshida, K.E. Buckton, M.C. Sparkes, A.P. Goggin, M.L. Rivas, P.S. Gerald, K. Simola, C.E. Wright, W.K. Stanford, J.A. Brown, R.C.P. Go, L. Scrafford-Wolff, P.M. Sinet, D.C. Rao, E.J. Yunis, A. Westerveld, L. R. Weitkamp, B. Sykes, M. Bobrow, N. Oliver, H.-H. Ropers, M.A. Ferguson-Smith, D. Borgaonkar, S. Piomelli, D. Bootsma, C.W. Bazinet, A.F. Wilson, H. Hameister, P.J.L. Cook, E. Herbschleb-Voogt, J.J. Yunis, P. Szabo, S. Philipps, W. R. Mayr, T.B. Shows, E.A. Azen, R.C. Schwartz, J.M. Vance, S. Leupe-de Smit, D. Swallow, A.C. Leary, Bjørnar Olaisen, R.C. Karn, Y. Shimizu, B.J.B. Keats, E. Solomon, M.L. Schroeder, T. Gedde-Dahl, O.J. Miller, V. Kirton, J. H. Olving, S. Brown, R. Roos, D. Cox, F. Pellett, L.Y. Wang, Timothy A. Donlon, R.E. Magenis, E.M. Helveston, N.C. Sun, A. de la Chapelle, J.M. Luciani, A. Heiberg, R.S. Lemons, D.L. George, C.R.Y. Sun, R.D.G. McKay, R.M. Denney, N. Lamvik, A.S. Baim, R. Schwab, I. Balazs, N.E. Morton, L. Pajunen, M. Blumenthal, J.R. Sawyer, Elizabeth B. Robson, R.E. Eisenman, M. Prensky, P.A. Lalley, K.M. Overton, T.M. Dijksman, L.C. Yu, J.A. Robinson, L.M.M. Wijnen, H. Kaita, R.C. Elston, S.J. O’Brien, J. Garver, M.A. Nijman, M. Monteba-van Heuvel, P.L. Pearson, S. Povey, Erik Thorsby, B. Lauras, P. M. Conneally, V.A. McKusick, E. Tolley, K. Willecke, A.D. Merritt, R. Moreland, P. Meera Khan, P. Pierce, T.H. Roderick, M.Y. Tsai, R. Johannsmann, T. Campana, A. Brøgger, E.W. Lovrien, R.L. Eddy, N. Suciu-Foca, C.G. Palmer, C. Jones, A.F. Gazdar, A. Shalev, M.K. Fagerhol, E. Johnston, J. Reiss, C.N. Fear, S. Burgess, L.L. Haley, S. Hempfling, W.S. Volkers, J. Gavin, Liao Law, Y. Boyd, A. Mayerová, J.H. Edwards, M.G. Byers, W. Stanley, L.R. Weitkamp, M.E. Duncan, H.J. Evans, L.J. Donald, B. Hellkuhl, F.H. Ruddle, I.L. Hansteen, B.M. Turner, I.W. Craig, K.-H. Grzeschik, T. Mohandas, A. Siverts, D.W. Ball, K.C. Atwood, R. Bigley, L. U. Lamm, R.S. Sparkes, M. Siniscalco, S. Arias, R.A. Fisher, M. Mota, E.R. Giblett, C.T. Falk, S. Guttormsen, N.R. Mendell, K. Hirschhorn, M. Smith, H. Oie, M.P. Cowmeadow, F.T. Kao, J. de Witt, N. Shimizu, E.A. Nichols, E.S. Seravalli, D.A. Aitken, R. Mausner, M. Hultén, M. Lewis, R. Saisson, A. Bratlie, A.E. Greene, P. Karli, J. Chamberlin, M.T. Davisson, P.J. McAlpine, C.W.H. Partridge, I. Berczi, W.F. Witterland, Veronica van Heyningen, B.P. Dorman, A.P.M. Jongsma, P. Rubinstein, B.B. Knowles, C. Verma, J. Wood, M.J. Champion, B. Pernis, R. Sanger, K.E. Toomey, A. Bennick, P.L. Yu, W.L. Marsh, V.M. Regina, B.A. Doppert, J.J. Garver, U. Francke, J. Fraisse, M.E. Chandler, G.A.P. Bruns, H. Vriesendorp, S. Rowe, A. Krüger, J.M. Robert, B.J. Mintz, K. Bender, R. Lange, T. Borun, J.A. Norton, T. Ho, J.E. Noades, M.A. Pericak-Vance, R.T. Taggart, N. Tanigaki, M.A. Craft, K. Berg, Matthew Parks, F. Freycon, D.P. Aden, C.A. Slaughter, H.J. Cooke, J.E. Anderson, E. Lovrien, A.W. Johnston, A. Estop, J. Parekh, W.G. Burgerhout, M.A. Pellegrino, J. Hemmerling, A.F. Naylor, J.L. Hamerton, S. Goodnight, D.B. Amos, C.K. Eun, D.L. Slate, R. Jonassen, J. Ott, R. Mierau, T.T. Puck, D. Warburton, M. Devictor-Vuillet, C.J. Sherr, R.H. Lindenbaum, H.P. Klinger, K.K. Namboodiri, M. Meisler, S. Rosenfeld, F. Varricchio, E.H.Y. Chu, B. Carritt, T. Philip, W. Bauch, and S.J. Jeremiah
Subjects: Index (economics), Statistics, Genetics, Subject (documents), Biology, Molecular Biology, Genetics (clinical)
Published: 1978
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44. Results and prospects of chromosomal gene transfer between cultured mammalian cells

Author: K. Willecke
Subjects: Genetics, biology, Somatic cell, Karyotype, General Medicine, biology.organism_classification, Genome, Molecular biology, Isozyme, Chinese hamster, HAT medium, Agronomy and Crop Science, Metaphase, Gene, Biotechnology
Abstract: The fusion of two somatic cells can be considered as the transfer of the total genome from one somatic cell to another somatic cell. During the last 20 years important methodical details of this gene transfer system, such as the isolation and characterization of suitable mutations, selection techniques, and procedures for isozyme and karyotype analyses to follow the segregation of chromosomes from hybrid cells, have been worked out (for reviews see Chu and Powell 1976; Ruddle and Creagan 1975). The knowledge of these basic experimental procedures was used in attempts to fractionate the genome of one cell and to use purified metaphase chromosomes as vectors for the transfer of genetic information into cultured recipient cells. The first convincing demonstration of chromosomal gene transfer was reported by McBride and Ozer (1973a) as the transfer of the gene coding for Chinese hamster hypoxanthine phosphoribosyl-transferase activity (HPRT) via purified chinese hamster chromosomes into established mouse L-A9 cells defective in functional mouse HPRT. Clerics which expressed Chinese hamster HPRT were grown in selective HAT medium containing hypoxanthine, aminopterin, and thymidine (Szybalska and Szybalski 1962; Litflefield 1964). The frequency of these gene transfer clones (or transferent cells as they will be referred to in this paper, see Degnen et al. (1976) was similar (1 . 10 -7) to that of spontaneous reversions in the defective mouse HPRT gene. Therefore the HPRT activity of every clone which grew up from chromosomal gene transfer experiments had to be analyzed in order to rule out revertant cell clones. Since this initial report, a number of laboratories have contributed further to the characterization and application of the chromosomal gene transfer system. The general statements to be presented in this review concerning the state of the transferred gene(s) (or transgenome as it will be referred to in this paper), appear to be a reasonable extraction of our present knowledge. It should be pointed out that in this review emphasis will be placed on the experimental conclusions of the rewieved papers. The major reports from different laboratories will be discussed under the corresponding heading summarized from the results of several contributions. For more experimental details the reader is referred to the original publications or to a previous review by McBride and Athwal (1976).
Published: 1978
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45. References to the committee reports

Author: L.R. Weitkamp, J.E. Anderson, F.A. McMorris, L. Komarnicki, O. Mutchinick, S.M. Elsevier, T. Mohandas, J.L. Hamerton, G. Miller, J.R. Gosden, E. Lovrien, D.R. Bolling, J. Fleming, H.J. Evans, G.J. Wullems, J. Prosser, N.C. Sun, H. Bosker, K.C. Atwood, W. Keijzer, H.M.A. Beyersbergen van Henegouwen, A.B. Bijnen, M.K. Fagerhol, J. Ott, J. van der Horst, E. Grace, C.W.H. Partridge, R.C. Miller, Y.-S. Teng, P.J. McAlpine, J.E. Gray, J. de Wit, H. van Someren, K. Willecke, K. Hirschhorn, V. Niewczas-Late, T.B. Shows, D.A. Hopkinson, A.E. Greene, L. Beckman, J.A. Pierce, H.A. de Wit-Verbeek, P.W. Teesdale, R. Kennett, E. Johnston, R.E. Giles, G.B. Côté, P.L. Pearson, E. Magenis, A.G.J.M. van der Linden, M. Bobrow, V.A. McKusick, N. van Cong, J.H. Edwards, A.D. Merritt, P. Meera Khan, R.G. Davidson, P.L. Townes, I. Schreuder, S.A. Sørensen, K.W. Jones, J. Frézal, M.L. Rivas, E.B. Robson, D. Weil, A. Hoogeveen, R.A. Buckland, J.J. van Rood, K.-H. Grzeschik, E. Jones, E.A. Nichols, W.F. Bodmer, P.J.L. Cook, D.S. Borgaonkar, L. Wang, E. Solomon, B. Olaisen, K. Fenger, A.S. Henderson, A.J.J. Reuser, A. Vust, G. Beckman, E.M. Wurzer-Figurelli, J.E. Syrett, W.G. Burgerhout, C.C. Chang, D. Kacian, Veronica van Heyningen, S.E. Gardiner, A.R. Mitchell, W.B. Bias, C.M. Giles, S. Chen, F. Hecht, J.A. Brown, N. Busby, H. Kaita, C.G. Palmer, D.A. Meyers, R.C. Elston, T.G. Gedde-Dahl, R.M. Baker, A.P.M. Jongsma, K. Berg, R.S. Kucherlapati, L.E. Nijenhuis, I. Purdom, R. Sanger, R.P. Clayton, U. Francke, J.K. McDougall, J. German, P.M. Ellis, S.M. Bowser Riley, P.M. Price, M. Lewis, S. Povey, E.H.Y. Chu, R.A. Oosterbaan, L.L. Coriell, P. Goodfellow, D. Mutton, K.P. Glen, C. Partridge, R.S.K. Chaganti, D. Bootsma, M. Fellous, W. Prensky, W.R.T. Los, D.M. Steffensen, G. Corneo, D.W. Buck, E.M. Eicher, A. Westerveld, B. Bengtsson, M.C. Rattazzi, F.H. Ruddle, E.R. Giblett, W.S. Volkers, R.P. Creagan, T. Gedde-Dahl, P.M Conneally, G.R. Douglas, M.A. Ferguson-Smith, H. Galjaard, C. Pangalos, R. Rebourcet, D. Bergsma, and A. Hagemeijer
Subjects: Genetics, Library science, Biology, Bioinformatics, Molecular Biology, Genetics (clinical)
Published: 1975
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46. Selective permeability of different connexin channels to the second messenger inositol 1,4,5-trisphosphate.

Author: H, Niessen, H, Harz, P, Bedner, K, Krmer, and K, Willecke
Abstract: Intercellular propagation of signals through connexin32-containing gap junctions is of major importance in physiological processes like nerve activity-dependent glucose mobilization in liver parenchymal cells and enzyme secretion from pancreatic acinar cells. In these cells, as in other organs, more than one type of connexin is expressed. We hypothesized that different permeabilities towards second messenger molecules could be one of the reasons for connexin diversity. In order to investigate this, we analyzed transmission of inositol 1,4,5-trisphosphate-mediated calcium waves in FURA-2-loaded monolayers of human HeLa cells expressing murine connexin26, -32 or -43. Gap junction-mediated cell coupling in different connexin-transfected HeLa cells was standardized by measuring the spreading of microinjected Mn(2+) that led to local quenching of FURA-2 fluorescence. Microinjection of inositol 1,4,5-trisphosphate into confluently growing HeLa connexin32 transfectants induced propagation of a Ca(2+) wave from the injected cell to neighboring cells that was at least three- to fourfold more efficient than in HeLa Cx26 cells and about 2.5-fold more efficient than in HeLa Cx43 transfectants. Our results support the notion that diffusion of inositol 1,4,5-trisphosphate through connexin32-containing gap junctions is essential for the optimal physiological response, for example by recruiting liver parenchymal cells that contain subthreshold levels of this short lived second messenger.
Published: 2000

47. Triacetic Acid Lactone, a Derailment Product of Fatty Acid Biosynthesis

Author: M. Yalpani, K. Willecke, and Feodor Lynen
Subjects: Electrophoresis, Chromatography, Paper, Ultraviolet Rays, Stereochemistry, Palmitic Acids, Acetates, Biochemistry, Ligases, Lactones, Saccharomyces, chemistry.chemical_compound, Methods, Organic chemistry, Coenzyme A, chemistry.chemical_classification, Triacetic acid lactone, Carbon Isotopes, Chemistry, Spectrum Analysis, Fatty Acids, Fatty acid, Malonates, Thin-layer chromatography, Yeast, Paper chromatography, Enzyme, Chromic acid, Chromatography, Thin Layer, Crystallization, Oxidation-Reduction, NADP, Stearic Acids, Lactone
Abstract: If no NADPH is available for reduction, fatty acid biosynthesis is blocked at the stage of the acetoacetyl-acyl carrier protein intermediate. In this case highly purified fatty acid synthetase from baker's yeast catalyzes, in a derailment reaction, the formation of triacetic acid lactone from acetyl- and malonyl-CoA. The identity of the product was shown by the enzymatic incorporation of radioactivity from [1-14C]acetyl-CoA and from recrystallization to constant specific radioactivity. In paper chromatography, thin layer chromatography, and ionophoresis both the chemically synthesized triacetic acid lactone and the enzymatically formed compound migrated with the same RF-values and electrophoretic mobility. By an oxidation with chromic acid according to the procedure of Kuhn-Roth it could be demonstrated that the radioactivity of [1-14C]acetyl-CoA is incorporated only into the C-6 position of triacetic acid lactone. Free triacetic acid and tetraacetic acid lactone do not seem to be formed by fatty acid synthetase. The ratio of the malonyl-CoA utilization for the synthesis of palmitoyl- and stearoyl-CoA to that for the synthesis of triacetic acid lactone was found to be about 90:1. The significance of these findings is discussed. A chemical mechanism for the formation of triacetic acid lactone by fatty acid synthetase is proposed.
Published: 1969
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48. Two homologous protein components of hepatic gap junctions

Author: David B. Teplow, Jean-Paul Revel, R. Dermietzel, K. Willecke, O. Traub, and Bruce J. Nicholson
Subjects: Transmembrane channels, Multidisciplinary, Molecular mass, Chemistry, Molecular Sequence Data, Cell, Gap junction, Antibodies, Monoclonal, Fluorescent Antibody Technique, Membrane Proteins, Protein superfamily, Connexins, Connexon, Rats, Molecular Weight, Mice, Intercellular Junctions, medicine.anatomical_structure, Liver, medicine, Biophysics, Animals, Amino Acid Sequence
Abstract: Gap junctions consist of closely packed pairs of transmembrane channels, the connexons, through which materials of low relative molecular mass diffuse from the cell to neighbouring cells. In liver, connexons consist of six protein summits1,2 which, until now, were believed to be identical3. However, besides the major polypeptide of relative molecular mass (Mr) 28,000 (and see refs 4 and 6), a component of Mr 21,000 (21K) has been repeatedly observed3–5 in liver. The amino-terminal sequence (18 residues) of this less abundant protein shows that it is related to, but distinct from, the Mr 28K protein. Immuno-staining and immuno-precipitation show both proteins to be in the same gap junctional plaques. Thus, it seems that hepatic gap junction channels (and by extension possibly others) are composed of two (or more) homologous proteins.
Published: 1987
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49. Adenovirus type 5 persisting in human lymphocytes is unlikely to be involved in immortalization of lymphoid cells by fusion with cytoplasts or by transfection with DNA of mouse L cells

Author: H, Abken, C, Bützler, and K, Willecke
Subjects: Cell Fusion, Mice, Adenoviruses, Human, Adenovirus Early Proteins, DNA, Viral, Animals, Humans, Lymphocytes, Oncogene Proteins, Viral, Transfection, Cell Line
Abstract: Human peripheral blood lymphocytes were induced to proliferate indefinitely in vitro by fusion with cytoplasts from mouse L 929 cells or, alternatively, by transfection with DNA isolated from L929 cytoplasts. Since adenoviruses epidemically infect human lymphocytes, the newly established cell lines were assayed for the presence of adenoviral DNA sequences. In 8 of 10 lymphoid cell lines of both B and T cell origin, adenovirus type 5 (serogroup C) DNA sequences were detected. The cells harbor approximately 40 to 70 genome copies per cell. Adenovirus type 5 transcripts of the E1A and E1B early regions that are responsible for the transforming capacity of adenoviruses could not be detected in the lymphoid cell lines. Therefore we conclude that the adenovirus genome persisting in immortalized lymphoid cells is not involved in the maintenance of indefinite proliferation induced by fusion with L929 cytoplasts or by DNA transfection.
Published: 1987

50. Proceedings: Transfer of the human gene (HGPRT) for hypoxanthine phosphoribosyltransferase (EC 2.4.2.8) on isolated human metaphase chromosomes into mouse cells

Author: K, Willecke and F H, Ruddle
Subjects: Hypoxanthine Phosphoribosyltransferase, Mice, Phosphoglycerate Kinase, Sex Chromosomes, Transformation, Genetic, Genes, Animals, Humans, Female, Glucosephosphate Dehydrogenase, HeLa Cells
Published: 1974

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