Your search keyword '"Janice E. Buss"' showing total 60 results

1. Campylobacter culture fails to correctly detect Campylobacter in 30% of positive patient stool specimens compared to non-cultural methods

Author

Blake W. Buchan, Janice E. Buss, David Craft, Michelle Cresse, Steve Young, and Susan Doyle

Subjects

Male, 0301 basic medicine, Culture, medicine.disease_cause, Gastroenterology, Feces, 0302 clinical medicine, Medical microbiology, Campylobacter spp, Campylobacter Infections, Prospective Studies, 030212 general & internal medicine, Child, Aged, 80 and over, Immunoassay, medicine.diagnostic_test, biology, Campylobacter, General Medicine, Middle Aged, Infectious Diseases, Molecular Diagnostic Techniques, Child, Preschool, Female, Original Article, Campylobacter upsaliensis, Adult, Microbiology (medical), medicine.medical_specialty, Adolescent, 030106 microbiology, Campylobacteriosis, Sensitivity and Specificity, Young Adult, 03 medical and health sciences, Internal medicine, Multiplex polymerase chain reaction, medicine, Humans, Aged, Composite reference method, Bacteriological Techniques, business.industry, Infant, 16S ribosomal RNA, biology.organism_classification, medicine.disease, business

Abstract

Campylobacter diagnosis is hampered because many laboratories continue to use traditional stool culture, which is slow and suffers false-negative results. This large multi-site study used a composite reference method consisting of a new FDA-cleared immunoassay and four molecular techniques to compare to culture. Prospectively collected patient fecal specimens (1552) were first preliminarily categorized as positive or negative by traditional culture. All specimens were also tested by EIA, and any EIA-positive or culture-discrepant results were further characterized by 16S rRNA qPCR, eight species-specific PCR assays, bidirectional sequencing, and an FDA-cleared multiplex PCR panel. The five non-culture methods showed complete agreement on all positive and discrepant specimens which were then assigned as true-positive or true-negative specimens. Among 47 true-positive specimens, culture incorrectly identified 13 (28%) as negative, and 1 true-negative specimen as positive, for a sensitivity of 72.3%. Unexpectedly, among the true-positive specimens, 4 (8%) were the pathogenic species C. upsaliensis. Culture had a 30% false result rate compared to immunoassay and molecular methods. More accurate results lead to better diagnosis and treatment of suspected campylobacteriosis.

Published

2019

2. Culture Methods to Determine the Limit of Detection and Survival in Transport Media of Campylobacter Jejuni in Human Fecal Specimens

Author

Janice E, Buss, Elizabeth, Thacker, and Michelle, Santiago

Subjects

Campylobacter jejuni, Feces, Microbial Viability, Genes, Bacterial, Limit of Detection, Culture Techniques, Colony Count, Microbial, Humans, Transportation, Culture Media

Abstract

A culture from human stool for diagnosis of Campylobacter-based intestinal illness takes several days, a wait that taxes the fortitude of the physician and the patient. A culture is also prone to false negative results from random loss of viability during specimen handling, overgrowth of other fecal flora, and poor growth of several pathogenic Campylobacter species on traditional media. These problems can confound clinical decisions on patient treatment and have limited the field from answering fundamental questions on Campylobacter growth and infections. We describe a procedure that estimates the lower limit of bacterial numbers that can be detected by a culture and a method for quantifying survival of C. jejuni in media used for transport of this fragile organism. Knowing this information, it becomes possible to set clinically relevant detection thresholds for diagnostic tests and address unstudied issues of whether non-symptomatic colonization is prevalent, if co-infection with other enteric pathogens is common, or if bacterial load correlates with symptoms or serious sequelae. The study also included testing of 1,552 prospectively collected patient diarrheal fecal specimens that were initially classified by conventional culture and further tested by a new enzyme immunoassay. Positive and discrepant specimens were then screened by four molecular methods to assign true-positive or true-negative status. The 5 non-culture methods showed complete agreement on all 48 positive and discrepant specimens, while the culture mis-identified 14 (28%). The specimens that were incorrectly identified by culture included 13 false negative and 1 false positive sample. This basic protocol can be used with multiple Campylobacter spp. and will allow the numbers of Campylobacter bacteria that produce symptoms of gastroenteritis in humans to be determined and for prevalence rates to be updated.

Published

2020

3. Effects ofEchinaceaextracts on macrophage antiviral activities

Author

Marian L. Kohut, Aisha E. Martin, Janice E. Buss, and David S. Senchina

Subjects

Pharmacology, Alpha interferon, Biology, Guanylate-binding protein, Microbiology, Nitric oxide synthase, Apoptosis, Cell culture, Interferon, medicine, biology.protein, Macrophage, Secretion, medicine.drug

Abstract

Type I interferons are a class of cytokines synthesized by leukocytes such as macrophages that limit viral replication. We hypothesized that one mechanism whereby Echinacea spp. extracts may enhance immunity is through modulating interferon-associated macrophage pathways. We used herpes simplex viral infection in the murine macrophage cell line RAW264.7 and monitored virus-induced cell death, interferon secretion, and two intracellular proteins that indicate activation of interferon pathways. Cells were incubated with control media or extracts from four different species (E. angustifolia, E. purpurea, E. tennesseensis, E. pallida). Cells incubated with extracts prior to infection showed very modest enhancement of viability, and no increase in the secretion of interferons alpha or beta as compared to control cells. Virus-infected macrophages treated with extracts from E. purpurea showed a small (

Published

2009

4. Transforming Activity of the Rho Family GTPase, Wrch-1, a Wnt-regulated Cdc42 Homolog, Is Dependent on a Novel Carboxyl-terminal Palmitoylation Motif

Author

Channing J. Der, Adam Shutes, Emily J. Chenette, Carolyn Weinbaum, Janice E. Buss, Audrey Minden, Adrienne D. Cox, and Anastacia C. Berzat

Subjects

rho GTP-Binding Proteins, Amino Acid Motifs, Blotting, Western, Green Fluorescent Proteins, Molecular Sequence Data, Palmitic Acid, Biotin, Endosomes, CDC42, GTPase, Biology, Transfection, Biochemistry, Mice, Cytosol, Prenylation, Palmitoylation, Cell Adhesion, Animals, Protein palmitoylation, Amino Acid Sequence, Cysteine, cdc42 GTP-Binding Protein, Molecular Biology, Peptide sequence, Cell Proliferation, Sequence Homology, Amino Acid, Cell Membrane, Esters, Cell Biology, Subcellular localization, Recombinant Proteins, Protein Structure, Tertiary, Cell biology, Microscopy, Fluorescence, Mutation, Mutagenesis, Site-Directed, NIH 3T3 Cells, Protein prenylation, Protein Binding, Signal Transduction

Abstract

Wrch-1 is a Rho family GTPase that shares strong sequence and functional similarity with Cdc42. Like Cdc42, Wrch-1 can promote anchorage-independent growth transformation. We determined that activated Wrch-1 also promoted anchorage-dependent growth transformation of NIH 3T3 fibroblasts. Wrch-1 contains a distinct carboxyl-terminal extension not found in Cdc42, suggesting potential differences in subcellular location and function. Consistent with this, we found that Wrch-1 associated extensively with plasma membrane and endosomes, rather than with cytosol and perinuclear membranes like Cdc42. Like Cdc42, Wrch-1 terminates in a CAAX tetrapeptide (where C is cysteine, A is aliphatic amino acid, and X is any amino acid) motif (CCFV), suggesting that Wrch-1 may be prenylated similarly to Cdc42. Most surprisingly, unlike Cdc42, Wrch-1 did not incorporate isoprenoid moieties, and Wrch-1 membrane localization was not altered by inhibitors of protein prenylation. Instead, we showed that Wrch-1 is modified by the fatty acid palmitate, and pharmacologic inhibition of protein palmitoylation caused mislocalization of Wrch-1. Most interestingly, mutation of the second cysteine of the CCFV motif (CCFV > CSFV), but not the first, abrogated both Wrch-1 membrane localization and transformation. These results suggest that Wrch-1 membrane association, subcellular localization, and biological activity are mediated by a novel membrane-targeting mechanism distinct from that of Cdc42 and other isoprenylated Rho family GTPases.

Published

2005

5. Distinct Rates of Palmitate Turnover on Membrane-bound Cellular and Oncogenic H-Ras

Author

Jonathan L. Coloff, Tara L. Baker, Hui Zheng, Joy Walker, and Janice E. Buss

Subjects

GTP', Acylation, Caveolin 1, Palmitic Acid, Fluorescent Antibody Technique, Biology, Transfection, Tritium, Caveolins, Guanosine Diphosphate, Biochemistry, 3T3 cells, Proto-Oncogene Proteins p21(ras), Mice, Sonication, chemistry.chemical_compound, Caveolae, Caveolin, medicine, Animals, Cysteine, Molecular Biology, Cysteine metabolism, Effector, Cell Membrane, 3T3 Cells, Cell Biology, Fibroblasts, Hydrogen-Ion Concentration, Cell biology, Kinetics, Genes, ras, medicine.anatomical_structure, Palmitoyl-CoA Hydrolase, chemistry, Guanosine Triphosphate, Half-Life

Abstract

H-Ras displays dynamic cycles of GTP binding and palmitate turnover. GTP binding is clearly coupled to activation, but whether the palmitoylated COOH terminus participates in signaling, especially when constrained by membrane tethering, is unknown. As a way to compare COOH termini of membrane-bound, lipid-modified H-Ras, palmitate removal rates were measured for various forms of H-Ras in NIH 3T3 cells. Depalmitoylation occurred slowly (t(1/2) approximately 2.4 h) in cellular (H-RasWT) or dominant negative (H-Ras17N) forms and more rapidly (t(1/2) approximately 1 h) in oncogenic H-Ras61L or H-RasR12,T59. Combining this data with GTP binding measurements, the palmitate half-life of H-Ras in the fully GTP-bound state was estimated to be less than 10 min. Slow palmitate removal from cellular H-Ras was not explained by sequestration in caveolae, as neither cellular nor oncogenic H-Ras showed alignment with caveolin by immunofluorescence. Conversely, although it had faster palmitate removal, oncogenic H-Ras was located in the same fractions as H-RasWT on four types of density gradients, and remained fully membrane-bound. Thus the different rates of deacylation occurred even though oncogenic and cellular H-Ras appeared to be in similar locations. Instead, these results suggest that acylprotein thioesterases access oncogenic H-Ras more easily because the conformation of its COOH terminus against the membrane is altered. This previously undetected difference could help produce distinctive effector interactions and signaling of oncogenic H-Ras.

Published

2003

6. Amyloid β-Peptide Decreases Neuronal Glucose Uptake Despite Causing Increase in GLUT3 mRNA Transcription and GLUT3 Translocation to the Plasma Membrane

Author

Walter H. Hsu, Janice E. Buss, Teerasak Prapong, Heather West Greenlee, Patricia A Heine, and Etsuro Uemura

Subjects

Snf3, Monosaccharide Transport Proteins, Transcription, Genetic, Glucose uptake, Nerve Tissue Proteins, Chromosomal translocation, Hippocampus, Membrane Fusion, Rats, Sprague-Dawley, Adenosine Triphosphate, Developmental Neuroscience, mental disorders, Extracellular, Animals, RNA, Messenger, Cells, Cultured, In Situ Hybridization, Neurons, Amyloid beta-Peptides, Glucose Transporter Type 3, biology, Vesicle, Cell Membrane, Glucose transporter, Peptide Fragments, Rats, Up-Regulation, Cell biology, Protein Transport, Cytosol, Glucose, Neurology, Biochemistry, Potassium, biology.protein, GLUT3

Abstract

Amyloid beta-peptide (Abeta) has been shown to impair glucose uptake in cultured hippocampal neurons and shortens their survival time. Abeta appears to inhibit neuronal glucose uptake by activating Gs-coupled receptors and the cAMP-PKA system. In this study, Abeta inhibition of neuronal glucose uptake was studied by assaying translocation of glucose transporter isoform GLUT3, transcription of GLUT3 mRNA, and fusion of GLUT3-containing vesicles with the plasma membrane. Cultured hippocampal neurons exposed to 10 microM Abeta25-35 or Abeta1-40 for 3 or 24 h showed a significant decrease in glucose uptake. To assess the regulatory role of Abeta on neuronal glucose uptake, translocation of GLUT3 from the cytosol to the plasma membrane was studied by the plasma membrane lawn assay and transcription of GLUT3 mRNA by in situ hybridization. In spite of a decrease in glucose uptake, Abeta25-35 and Abeta1-40 (10 microM) markedly promoted GLUT3 translocation to the plasma membrane by 30 min. Abeta25-35 also up-regulated transcription of GLUT3 mRNA by 12 h. High extracellular K(+) increased immunolabeling of the exofacial (i.e., extracellular) epitope of GLUT3 at the plasma membrane and Abeta25-35 inhibited this increase. Based on these data we propose that Abeta increases translocation of GLUT3-containing vesicles, but inhibits their fusion with the plasma membrane.

Published

2002

7. Murine Guanylate-binding Protein: Incomplete Geranylgeranyl Isoprenoid Modification of an Interferon-γ–inducible Guanosine Triphosphate-binding Protein

Author

John T. Stickney and Janice E. Buss

Subjects

Geranylgeranyl Transferase, Molecular Sequence Data, Protein Prenylation, Mevalonic Acid, Guanosine triphosphate, Biology, Tritium, Article, Cell Line, Interferon-gamma, Mice, chemistry.chemical_compound, Geranylgeranylation, GTP-binding protein regulators, Prenylation, GTP-Binding Proteins, Animals, Humans, Amino Acid Sequence, Molecular Biology, Alkyl and Aryl Transferases, Binding Sites, Farnesyl Transferase Inhibitor, Binding protein, Cell Membrane, Cell Biology, DNA-Binding Proteins, Biochemistry, chemistry, Isotope Labeling, COS Cells, Protein prenylation, lipids (amino acids, peptides, and proteins), Rabbits

Abstract

Farnesylation of Ras proteins is necessary for transforming activity. Although farnesyl transferase inhibitors show promise as anticancer agents, prenylation of the most commonly mutated Ras isoform, K-Ras4B, is difficult to prevent because K-Ras4B can be alternatively modified with geranylgeranyl (C20). Little is known of the mechanisms that produce incomplete or inappropriate prenylation. Among non-Ras proteins with CaaX motifs, murine guanylate-binding protein (mGBP1) was conspicuous for its unusually low incorporation of [3H]mevalonate. Possible problems in cellular isoprenoid metabolism or prenyl transferase activity were investigated, but none that caused this defect was identified, implying that the poor labeling actually represented incomplete prenylation of mGBP1 itself. Mutagenesis indicated that the last 18 residues of mGBP1 severely limited C20 incorporation but, surprisingly, were compatible with farnesyl modification. Features leading to the expression of mutant GBPs with partial isoprenoid modification were identified. The results demonstrate that it is possible to alter a protein's prenylation state in a living cell so that graded effects of isoprenoid on function can be studied. The C20-selective impairment in prenylation also identifies mGBP1 as an important model for the study of substrate/geranylgeranyl transferase I interactions.

Published

2000

8. S-Nitrosocysteine Increases Palmitate Turnover on Ha-Ras in NIH 3T3 Cells

Author

Michelle A. Booden, Janice E. Buss, and Tara L. Baker

Subjects

GTP', Palmitates, Transferrin receptor, Lipid-anchored protein, Biochemistry, 3T3 cells, Mice, Palmitoylation, Caveolin, medicine, Animals, Cysteine, Phosphorylation, Molecular Biology, Monomeric GTP-Binding Proteins, S-Nitrosothiols, Chemistry, Kinase, 3T3 Cells, Cell Biology, Cell biology, medicine.anatomical_structure, Nitroso Compounds, Signal Transduction

Abstract

Ha-Ras is modified by isoprenoid on Cys(186) and by reversibly attached palmitates at Cys(181) and Cys(184). Ha-Ras loses 90% of its transforming activity if Cys(181) and Cys(184) are changed to serines, implying that palmitates make important contributions to oncogenicity. However, study of dynamic acylation is hampered by an absence of methods for acutely manipulating Ha-Ras palmitoylation in living cells. S-nitrosocysteine (SNC) and, to a more modest extent, S-nitrosoglutathione were found to rapidly increase [(3)H]palmitate incorporation into cellular or oncogenic Ha-Ras in NIH 3T3 cells. In contrast, SNC decreased [(3)H]palmitate labeling of the transferrin receptor and caveolin. SNC accelerated loss of [(3)H]palmitate from Ha-Ras, implying that SNC stimulated deacylation and permitted subsequent reacylation of Ha-Ras. SNC also decreased Ha-Ras GTP binding and inhibited phosphorylation of the kinases ERK1 and ERK2 in NIH 3T3 cells. Thus, SNC altered two important properties of Ha-Ras activation state and lipidation. These results identify SNC as a new tool for manipulating palmitate turnover on Ha-Ras and for studying requirements of repalmitoylation and the relationship between palmitate cycling, membrane localization, and signaling by Ha-Ras.

Published

2000

9. Transient Palmitoylation Supports H-Ras Membrane Binding but Only Partial Biological Activity

Author

Janice E. Buss, Michelle A. Booden, and Sarah G. Coats

Subjects

Base Sequence, Recombinant Fusion Proteins, organic chemicals, Molecular Sequence Data, Palmitic Acid, Membrane Proteins, Biological activity, 3T3 Cells, Oncogene Protein p21(ras), Biology, PC12 Cells, environment and public health, Biochemistry, Rats, Mice, Membrane interaction, Palmitoylation, COS Cells, Neurites, Animals, lipids (amino acids, peptides, and proteins), Membrane binding, Amino Acid Sequence

Abstract

H-Ras is95% membrane-bound when modified by farnesyl and palmitate, but10% membrane-bound if only farnesyl is present, implying that palmitate provides major support for membrane interaction. However the direct contribution of palmitate to H-Ras membrane interaction or the extent of its cooperation with farnesyl is unknown, because in the native protein the isoprenoid must be present before palmitate can be attached. To examine if palmitates can maintain H-Ras membrane association despite multiple cycles of turnover, a nonfarnesylated H-Ras(Cys186Ser) was constructed, with an N-terminal palmitoylation signal, derived from the GAP-43 protein. Although 40% of the GAP43:Ras(61Leu,186Ser) protein (G43:Ras61L) partitioned with membranes, the chimera had less than 10% of the transforming activity of fully lipidated H-Ras(61Leu) in NIH 3T3 cells. Poor focus formation was not due to incorrect targeting or gross structural changes, because G43:Ras61L localized specifically to plasma membranes and triggered differentiation of PC12 cells as potently as native H-Ras61L. Proteolytic digestion indicated that in G43:Ras61L both the N-terminal and the two remaining C-terminal cysteines of G43:Ras61L were palmitoylated. A mutant lacking all three C-terminal Cys residues had decreased membrane binding and differentiating activity. Therefore, even with correct targeting and palmitates at the C-terminus, G43:Ras61L was only partially active. These results indicate that although farnesyl and palmitate share responsibility for H-Ras membrane binding, each lipid also has distinct functions. Farnesyl may be important for signaling, especially transformation, while palmitates may provide potentially dynamic regulation of membrane binding.

Published

1999

10. Transplantation of BDNF-Secreting Mesenchymal Stem Cells Provides Neuroprotection in Chronically Hypertensive Rat Eyes

Author

Sinisa D. Grozdanic, Markus H. Kuehn, Janice E. Buss, Daniel Zamzow, Donald S. Sakaguchi, Bas Blits, Randy H. Kardon, and Matthew M. Harper

Subjects

genetic structures, Ocular hypertension, Pharmacology, Mesenchymal Stem Cell Transplantation, Neuroprotection, Retina, Neurotrophic factors, Rats, Inbred BN, Optic Nerve Diseases, Electroretinography, Medicine, Animals, Brain-derived neurotrophic factor, medicine.diagnostic_test, business.industry, Brain-Derived Neurotrophic Factor, Mesenchymal stem cell, Mesenchymal Stem Cells, Optic Nerve, Anatomy, Articles, medicine.disease, eye diseases, Rats, Transplantation, Vitreous Body, Disease Models, Animal, medicine.anatomical_structure, Treatment Outcome, Chronic Disease, Ocular Hypertension, sense organs, business

Abstract

To evaluate the ability of mesenchymal stem cells (MSCs) engineered to produce and secrete brain-derived neurotrophic factor (BDNF) to protect retinal function and structure after intravitreal transplantation in a rat model of chronic ocular hypertension (COH).COH was induced by laser cauterization of trabecular meshwork and episcleral veins in rat eyes. COH eyes received an intravitreal transplant of MSCs engineered to express BDNF and green fluorescent protein (BDNF-MSCs) or just GFP (GFP-MSCs). Computerized pupillometry and electroretinography (ERG) were performed to assess optic nerve and retinal function. Quantification of optic nerve damage was performed by counting retinal ganglion cells (RGCs) and evaluating optic nerve cross-sections.After transplantation into COH eyes, BDNF-MSCs preserved significantly more retina and optic nerve function than GFP-MSC-treated eyes when pupil light reflex (PLR) and ERG function were evaluated. PLR analysis showed significantly better function (P = 0.03) in BDNF-MSC-treated eyes (operated/control ratio = 63.00% ± 11.39%) than GFP-MSC-treated eyes (operated/control ratio = 31.81% ± 9.63%) at 42 days after surgery. The BDNF-MSC-transplanted eyes also displayed a greater level of RGC preservation than eyes that received the GFP-MSCs only (RGC cell counts: BDNF-MSC-treated COH eyes, 112.2 ± 19.39 cells/section; GFP-MSC-treated COH eyes, 52.21 ± 11.54 cells/section; P = 0.01).The authors have demonstrated that lentiviral-transduced BDNF-producing MSCs can survive in eyes with chronic hypertension and can provide retina and optic nerve functional and structural protection. Transplantation of BDNF-producing stem cells may be a viable treatment strategy for glaucoma.

Published

2011

11. The carboxyl-terminal CXXX sequence of Gi alpha, but not Rab5 or Rab11, supports Ras processing and transforming activity

Author

Janice E. Buss, Suzanne M. Graham, Adrienne D. Cox, Channing J. Der, and Patricia A. Solski

Subjects

Biochemistry, Prenylation, G protein, Heterotrimeric G protein, Protein prenylation, Context (language use), Biological activity, Cell Biology, Rab, Biology, Molecular Biology, G alpha subunit

Abstract

Although the heterotrimeric Gi alpha subunit terminates in an apparent CXXX prenylation signal (CGLF), it is not modified by isoprenylation. To determine if the Gi alpha CXXX sequence can signal prenylation when placed at the carboxyl termini of normally prenylated proteins, we have characterized the processing and biological activity of chimeric oncogenic Ras proteins that terminate in the Gi alpha CXXX sequence (Ras/Gi alpha). Surprisingly, these chimeras were prenylated both in vivo and in vitro, demonstrated significant membrane association, exhibited transforming activity, and induced transcriptional transactivation from Ras-responsive elements. We then extended these studies to determine if, unlike the CC or CXC carboxyl-terminal sequences of other Rab proteins, the carboxyl-terminal CXXX sequences of the Ras-related Rab5 and Rab11 proteins represent conventional CXXX prenylation signals that can support Ras processing and transforming activity. Unexpectedly, these Ras/Rab chimeras were nonprenylated, were cytosolic, and lacked detectable transforming or transcriptional transactivation activity. Taken together, these results suggest that the context within which a CXXX sequence occurs may also critically control the modification of a protein by prenylation, and that the Rab5 and Rab11 carboxyl termini do not possess conventional CXXX sequences. Instead, their CCXX and CCXXX motifs may represent additional classes of protein prenylation signals.

Published

1993

12. The Influence of Intracellular Location on Function of Ras Proteins

Author

Jodi McKay and Janice E. Buss

Subjects

Communication, business.industry, education, Biology, business, Neuroscience, Intracellular, Function (biology)

Abstract

Publisher Summary There are two ways that Ras proteins might come to be at multiple locations within a cell. Knowledge of the vehicles, regulation of departure, and speed of Ras movement are the key to understanding signaling in this scenario. Multiple studies give glimpses of both scenarios, and show that experimental manipulation of the location of introduced Ras proteins is a tactic that can alter Ras signaling. The major shift in our understanding that has come from the study of these trafficking events is that Ras proteins are not docile travelers; in response to mitogens, they can actively signal from both cell surface and internal membrane. The challenge ahead is to find ways to apply these driving lessons to endogenous Ras proteins and learn if this helps steer Ras away from oncogenic destinations. The experiments that begin to answer these questions are described in this chapter.

Published

2010

13. Structure and biological effects of lipid modifications on proteins

Author

Marie Chow, Janice E. Buss, and Channing J. Der

Subjects

Protein function, Protein Prenylation, Proteins, Cell Biology, Biology, Lipids, Cell biology, Biochemistry, Animals, Humans, lipids (amino acids, peptides, and proteins), MARCKS, Protein Processing, Post-Translational, Acyltransferases, Phospholipids, Cellular localization

Abstract

Both the prevalence of lipid modifications of proteins and their importance for protein function and cellular localization have been widely observed. The advances made during the past year in defining the enzymology of lipid addition and in understanding the biological consequences of these modifications on protein function are discussed.

Published

1992

14. Isoprenoid addition to Ras protein is the critical modification for its membrane association and transforming activity

Author

Channing J. Der, Kiyoko Kato, Janice E. Buss, Mark M. Hisaka, Suzanne M. Graham, and Adrienne D. Cox

Subjects

Proteolysis, Molecular Sequence Data, Biology, Methylation, environment and public health, Proto-Oncogene Proteins p21(ras), Mice, Endopeptidases, medicine, Animals, Amino Acid Sequence, Peptide sequence, chemistry.chemical_classification, Multidisciplinary, medicine.diagnostic_test, Farnesyl Transferase Inhibitor, Cell Membrane, Biological activity, 3T3 Cells, Farnesol, Cell Compartmentation, Amino acid, Cell Transformation, Neoplastic, chemistry, Biochemistry, Mutagenesis, Site-Directed, Protein Processing, Post-Translational, Research Article, Cysteine

Abstract

We have introduced a variety of amino acid substitutions into carboxyl-terminal CA1A2X sequence (C = cysteine; A = aliphatic; X = any amino acid) of the oncogenic [Val12]Ki-Ras4B protein to identify the amino acids that permit Ras processing (isoprenylation, proteolysis, and carboxyl methylation), membrane association, and transformation in cultured mammalian cells. While all substitutions were tolerated at the A1 position, substitutions at A2 and X reduced transforming activity. The A2 residue was important for both isoprenylation and AAX proteolysis, whereas the X residue dictated the extent and specificity of isoprenoid modification only. Differences were observed between Ras processing in living cells and farnesylation efficiency in a cell-free system. Finally, one farnesylated mutant did not undergo either proteolysis or carboxyl methylation but still displayed efficient membrane association (approximately 50%) and transforming activity, indicating that farnesylation alone can support Ras transforming activity. Since both farnesylation and carboxyl methylation are critical for yeast a-factor biological activity, the three CAAX-signaled modifications may have different contributions to the function of different CAAX-containing proteins.

Published

1992

15. Effects of Echinacea extracts on macrophage antiviral activities

Author

David S, Senchina, Aisha E, Martin, Janice E, Buss, and Marian L, Kohut

Subjects

Mice, Cell Survival, GTP-Binding Proteins, Plant Extracts, Macrophages, Animals, Interferon-alpha, Nitric Oxide Synthase Type II, Simplexvirus, Interferon-beta, Echinacea, Cell Line

Abstract

Type I interferons are a class of cytokines synthesized by leukocytes such as macrophages that limit viral replication. We hypothesized that one mechanism whereby Echinacea spp. extracts may enhance immunity is through modulating interferon-associated macrophage pathways. We used herpes simplex viral infection in the murine macrophage cell line RAW264.7 and monitored virus-induced cell death, interferon secretion, and two intracellular proteins that indicate activation of interferon pathways. Cells were incubated with control media or extracts from four different species (E. angustifolia, E. purpurea, E. tennesseensis, E. pallida). Cells incubated with extracts prior to infection showed very modest enhancement of viability, and no increase in the secretion of interferons alpha or beta as compared to control cells. Virus-infected macrophages treated with extracts from E. purpurea showed a small (2-fold) induction of guanylate binding protein (GBP) production, but no effect of extracts from other species was observed. In virus-infected cells, all the extracts increased the amount of inducible nitric oxide synthase (iNOS) protein, and this effect varied by type of extraction preparation. Together, these results suggest that any potential antiviral activities of Echinacea spp. extracts are likely not mediated through large inductions of Type I interferon, but may involve iNOS.

Published

2009

16. Characterization of the retinal proteome during rod photoreceptor genesis

Author

Heather West Greenlee, Oksana Kohutyuk, Alison E Barnhill, Laura A. Hecker, Janice E. Buss, and Vasant Honavar

Subjects

genetic structures, Cell, Short Report, lcsh:Medicine, Cell fate determination, Biology, Proteomics, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, medicine, lcsh:Science (General), Protein spot, lcsh:QH301-705.5, 030304 developmental biology, Medicine(all), Genetics, 0303 health sciences, Biochemistry, Genetics and Molecular Biology(all), lcsh:R, Retinal, General Medicine, eye diseases, Cell biology, Rod Photoreceptors, medicine.anatomical_structure, lcsh:Biology (General), chemistry, Mouse Retina, Proteome, sense organs, 030217 neurology & neurosurgery, lcsh:Q1-390

Abstract

Background The process of rod photoreceptor genesis, cell fate determination and differentiation is complex and multi-factorial. Previous studies have defined a model of photoreceptor differentiation that relies on intrinsic changes within the presumptive photoreceptor cells as well as changes in surrounding tissue that are extrinsic to the cell. We have used a proteomics approach to identify proteins that are dynamically expressed in the mouse retina during rod genesis and differentiation. Findings A series of six developmental ages from E13 to P5 were used to define changes in retinal protein expression during rod photoreceptor genesis and early differentiation. Retinal proteins were separated by isoelectric focus point and molecular weight. Gels were analyzed for changes in protein spot intensity across developmental time. Protein spots that peaked in expression at E17, P0 and P5 were picked from gels for identification. There were 239 spots that were picked for identification based on their dynamic expression during the developmental period of maximal rod photoreceptor genesis and differentiation. Of the 239 spots, 60 of them were reliably identified and represented a single protein. Ten proteins were represented by multiple spots, suggesting they were post-translationally modified. Of the 42 unique dynamically expressed proteins identified, 16 had been previously reported to be associated with the developing retina. Conclusions Our results represent the first proteomics study of the developing mouse retina that includes prenatal development. We identified 26 dynamically expressed proteins in the developing mouse retina whose expression had not been previously associated with retinal development.

Published

2009

17. The COOH-terminal domain of the Rap1A (Krev-1) protein is isoprenylated and supports transformation by an H-Ras:Rap1A chimeric protein

Author

P. J. Casey, Kiyoko Kato, Patricia A. Solski, Channing J. Der, R. Clark, G. M. Bokoch, Janice E. Buss, L. A. Quilliam, F. McCormick, and G. Wong

Subjects

Signal peptide, Recombinant Fusion Proteins, DNA Mutational Analysis, Palmitates, Rap GTP-binding protein, In Vitro Techniques, Moths, Biology, Methylation, Proto-Oncogene Proteins p21(ras), Structure-Activity Relationship, Prenylation, GTP-Binding Proteins, Animals, Cloning, Molecular, Molecular Biology, Peptide sequence, Cells, Cultured, Terpenes, Binding protein, Membrane Proteins, Cell Biology, Fusion protein, rap GTP-Binding Proteins, Membrane protein, Biochemistry, Protein Processing, Post-Translational, Research Article

Abstract

Although the Rap1A protein resembles the oncogenic Ras proteins both structurally and biochemically, Rap1A exhibits no oncogenic properties. Rather, overexpression of Rap1A can reverse Ras-induced transformation of NIH 3T3 cells. Because the greatest divergence in amino acid sequence between Ras and Rap1A occurs at the COOH terminus, the role of this domain in the opposing biological activities of these proteins was examined. COOH-terminal processing and membrane association of Rap1A were studied by constructing and expressing a chimeric protein (composed of residues 1 to 110 of an H-Ras activated by a Leu-61 mutation attached to residues 111 to 184 of Rap1A) in NIH 3T3 cells and a full-length human Rap1A protein in a baculovirus-Sf9 insect cell system. Both the chimeric protein and the full-length protein were synthesized as a 23-kDa cytosolic precursor that rapidly bound to membranes and was converted into a 22-kDa form that incorporated label derived from [3H]mevalonate. The mature 22-kDa form also contained a COOH-terminal methyl group. Full-length Rap1A, expressed in insect cells, was modified by a C20 (geranylgeranyl) isoprenoid. In contrast, H-Ras, expressed in either Sf9 insect or NIH 3T3 mouse cells contained a C15 (farnesyl) group. This suggests that the Rap1A COOH terminus is modified by a prenyl transferase that is distinct from the farnesyl transferase that modifies Ras proteins. Nevertheless, in NIH 3T3 cells the chimeric Ras:Rap1A protein retained the transforming activity conferred by the NH2-terminal Ras61L domain. This demonstrates that the modifications and localization signals of the COOH terminus of Rap1A can support the interactions between H-Ras and membranes that are required for transformation.

Published

1991

18. Metabolic radiolabeling techniques for identification of prenylated and fatty acylated proteins

Author

Janice E. Buss and Susanne M. Mumby

Subjects

Protein acylation, Prenylation, Biochemistry, Affinity chromatography, Immunoprecipitation, Biology, Differential expression, Molecular Biology, General Biochemistry, Genetics and Molecular Biology, Cellular proteins

Abstract

Lipid modifications of proteins can be detected by incubation of cultured cells with radioactive precursors followed by detergent extraction of protein and analysis of the extract by SDS-PAGE and fluorography. Identification of particular proteins requires immunoprecipitation, affinity purification, or differential expression (such as overexpression) before SDS-PAGE analysis. The purpose of this article is to present a brief description of protein acylation and prenylation modifications that have been observed and the details of how to detect the modifications by metabolic radiolabeling of cellular proteins.

Published

1990

19. H-Ras does not need COP I- or COP II-dependent vesicular transport to reach the plasma membrane

Author

Jodi McKay, Hui Zheng, and Janice E. Buss

Subjects

Golgi Apparatus, Antineoplastic Agents, Biology, Biochemistry, Microtubules, Exocytosis, Coat Protein Complex I, Proto-Oncogene Proteins p21(ras), chemistry.chemical_compound, symbols.namesake, Mice, Chlorocebus aethiops, Animals, Molecular Biology, COPII, Secretory pathway, Monomeric GTP-Binding Proteins, Protein Synthesis Inhibitors, Brefeldin A, Endoplasmic reticulum, Nocodazole, Cell Membrane, Cell Biology, COPI, Golgi apparatus, Cell biology, Vesicular transport protein, Protein Transport, chemistry, COS Cells, Mutation, symbols, NIH 3T3 Cells, COP-Coated Vesicles

Abstract

Although vesicular transport of the H-Ras protein from the Golgi to the plasma membrane is well known, additional trafficking steps, both to and from the plasma membrane, have also been described. Notably, both vesicular and nonvesicular transport mechanisms have been proposed. The initial trafficking of H-Ras to the plasma membrane was therefore examined in more detail. In untreated cells, H-Ras appeared at the plasma membrane more rapidly than a protein carried by the conventional exocytic pathway, and no H-Ras was visible on Golgi membranes in >80% of the cells. H-Ras was still able to reach the plasma membrane when COP II-directed transport was disrupted by two different mutant forms of Sar1, when COP I-mediated vesicular traffic from the endoplasmic reticulum to the Golgi was inhibited with brefeldin A, or when microtubules were disrupted by nocodazole. Although some H-Ras was present in the secretory pathway, protein that reached the membranes of the endoplasmic reticulum-Golgi intermediate compartment was unable to move further in the presence of nocodozale. These results identify an alternative mechanism for H-Ras trafficking that circumvents conventional COPI-, COPII-, and microtubule-dependent vesicular transport. Thus, H-Ras has two simultaneous but distinct means of transport and need not depend on vesicular trafficking for its delivery to the plasma membrane.

Published

2007

20. Glucose uptake in PC12 cells: GLUT3 vesicle trafficking and fusion as revealed with a novel GLUT3-GFP fusion protein

Author

M. Heather West Greenlee, Etsuro Uemura, Susan Carpenter, Janice E. Buss, and Robert T. Doyle

Subjects

Vesicle fusion, Time Factors, Monosaccharide Transport Proteins, Glucose uptake, Recombinant Fusion Proteins, Green Fluorescent Proteins, Vesicular Transport Proteins, Syntaxin 1, Nerve Tissue Proteins, Biology, Membrane Fusion, PC12 Cells, Exocytosis, Cellular and Molecular Neuroscience, Animals, Humans, Transport Vesicles, Membrane Glycoproteins, Microscopy, Confocal, Glucose Transporter Type 3, Cell Membrane, Glucose transporter, SNAP25, Membrane Proteins, Munc-18, Kiss-and-run fusion, Fusion protein, Immunohistochemistry, Cell biology, Rats, Luminescent Proteins, Glucose, Antigens, Surface, biology.protein, Potassium, SNARE Proteins, GLUT3

Abstract

The distribution of glucose transporters at the cell surface has a major impact on cellular glucose uptake. In muscle cells and adipocytes, this distribution is under the control of insulin; however, neuronal glucose uptake is not acutely regulated by insulin. Factors that affect the translocation of the neuronal glucose transporter isoform GLUT3 vesicles to and their fusion with the plasma membrane are not well understood. We report that GLUT3 in PC12 cells colocalizes with SNARE complex proteins SNAP-25 and syntaxin 1, suggesting that fusion of GLUT3-containing vesicles with the plasma membrane is mediated by these proteins. In addition, it seems that GLUT3 vesicle fusion is regulated, as depolarization increases GLUT3 insertion into the plasma membrane. To study the dynamics of GLUT3 vesicle trafficking, we have created a GLUT3-GFP fusion protein that is easily expressed in PC12 cells. Trafficking of GLUT3-GFP seems normal, as 1). its distribution is similar to endogenous GLUT3, 2). GLUT3-GFP containing vesicles fuse with the plasma membrane evidenced by labeling of the fusion protein with an antibody directed against the exofacial epitope of GLUT3, and 3). glucose uptake is similar to PC12 cells not transfected with GLUT3 fusion protein. These studies are the first to examine GLUT3 trafficking and fusion in PC12 cells, and establish a model system to study regulation of the neuronal glucose transporter.

Published

2003

21. Membrane Targeting: Methods

Author

Janice E. Buss

Subjects

Membrane protein, Membrane lipids, Peripheral membrane protein, Translocase of the inner membrane, Membrane fluidity, Biological membrane, Protein–lipid interaction, Biology, Integral membrane protein, Cell biology

Abstract

Receptor proteins in the outer cell membrane transmit environmental signals into the cell by the recruitment and assembly of internal proteins in an organized complex around the receptor on the inner surface of the cell membrane. Lipids (fats) that are physically attached to some proteins in these complexes help to tether key components to the lipid bilayer of the membrane to increase signalling efficiency. Scientists have learned how to introduce these membrane-targeting lipids into many proteins to produce and study how this may alter cell behaviour. Keywords: fatty acid modification; lipid bilayer; membrane proteins; protein design; chimaeric protein

Published

2003

22. Contributors

Author

John M. Abrams, John P. Adelman, Joseph L. Alcorn, Dario R. Alessi, Emil Alexov, Simon Alford, Kari Alitalo, James P. Allison, Steven C. Almo, Christelle Alory, Aymen Al-Shamkhani, Sally A. Amundson, Carl W. Anderson, Jannik N. Andersen, Peter Angel, Ettore Appella, William J. Arendshorst, Steve Arkinstall, Anjon Audhya, Joseph Avruch, Gary D. Bader, Cinzia Bagala, William E. Balch, Jesus Balsinde, Utpal Banerjee, David Barford, Dafna Bar-Sagi, Perry F. Bartlett, Philippe I.H. Bastiaens, Chiara Battelli, Linnea M. Baudhuin, Andrew J. Beavil, Rebecca L. Beavil, Joseph A. Beavo, Elsa Bello-Reuss, Stephen Bellum, Juan Carlos Izpisúa Belmonte, Craig B. Bennett, Jeffrey L. Benovic, Michael J. Berridge, Penny J. Beuning, Rashna Bhandari, Ananya Bhattacharya, Martin Biel, Vincent A. Bielinski, Hana Bilak, Lutz Birnbaumer, Geoff Birrell, Gail A. Bishop, Trillium Blackmer, Perry J. Blackshear, Christine Blattner, Mordecai P. Blaustein, Gary M. Bokoch, Lynda F. Bonewald, Marco Bonomi, Michelle A. Booden, Charles Boone, Martin D. Bootman, Johannes L. Bos, Jane M. Bradbury, Ralph A. Bradshaw, Anne R. Bresnick, Lena Brevnova, Ross I. Brinkworth, Michael S. Brown, Steven A. Brown, Anne Brunet, Robert Bucki, Robert D. Burgoyne, Janice E. Buss, Ronald A. Butow, Javier Capdevila, Ernesto Carafoli, Cathrine R. Carlson, Graham Carpenter, Juan J. Carrillo, Patrick J. Casey, William A. Catterall, Richard A. Cerione, Gianni Cesareni, Andrew C. Chan, Geoffrey Chang, Moses V. Chao, Harry Charbonneau, Philip Chen, Alan Cheng, Chris Chiu, Dar-chone Chow, Ted D. Chrisman, Anne Elisabeth Christensen, Jee Y. Chung, Grant C. Churchill, Aaron Ciechanover, Gino Cingolani, Sylvie Claeysen, Jean Closset, Shamshad Cockcroft, Patricia T.W. Cohen, Philip Cohen, Roger J. Colbran, Clay E.S. Comstock, Marco Conti, Jackie D. Corbin, Daniela Corda, Sabine Costagliola, Rick H. Cote, Shaun R. Coughlin, L. Ashley Cowart, Adrienne D. Cox, Mark S. Cragg, José L. Crespo, Claudia Crosio, Christopher Daly, Sami Damak, Mary Dasso, Michael David, Anthony J. Davis, Roger J. Davis, Richard N. Day, Eva Degerman, Warren L. DeLano, Mark L. Dell'Acqua, Emmanuèle Délot, Bruce Demple, Edward A. Dennis, John M. Denu, Anna A. DePaoli-Roach, Channing J. Der, Johan de Rooij, Frederic de Sauvage, Peter N. Devreotes, Valérie Dewaste, Robert B. Dickson, Becky A. Diebold, Pier Paolo Di Fiori, Maria Di Girolamo, Julie Diplexcito, Jack E. Dixon, Robert W. Doms, Daniel J. Donoghue, Russell F. Doolittle, Stein Ove Døskeland, Wolfgang R.G. Dostmann, Matthias K. Dreyer, Guo Guang Du, Keyong Du, Michael R. Duchen, William G. Dunphy, Joanne Durgan, Michael L. Dustin, Peter A. Edwards, Jackson G. Egen, Lee E. Eiden, Elaine A. Elion, Scott Emr, Othmar G. Engelhardt, Christophe Erneux, Peter J. Espenshade, Edward D. Esplin, B. Mark Evers, Joanne L. Eyles, Sheelagh Fame, Marilyn Farquhar, Robert Feil, Gui-Jie Feng, Stanley Fields, James J. Fiordalisi, Richard A. Firtel, Garret A. Fitzgerald, Andrew Flint, Marco Foiani, Barry Marc Forman, Albert J. Fornace, Sharron H. Francis, Günter Fritz, David A. Fruman, Antony Galione, Chris S. Gandhi, David L. Garbers, K. Christopher Garcia, Benjamin Geiger, Larry Gerace, Andrea Gerstner, Amato J. Giaccia, Michele Giannattasio, Vincent Giguère, Christopher K. Glass, Martin J. Glennie, Jennifer L. Glick, Joseph L. Goldstein, Venkatesh Gopal, Myriam Gorospe, Cedric Govaerts, Paul R. Graves, Patrick W. Gray, Irene Graziani, Douglas R. Green, Michael E. Greenberg, Iva Greenwald, Haihua Gu, Nuri Gueven, J. Silvio Gutkind, Jesper Z. Haeggström, Alan Hall, Michael N. Hall, Otto Haller, Heidi E. Hamm, Yusef A. Hannun, Carl A. Hansen, T. Kendall Harden, D. Grahame Hardie, Kiminori Hasegawa, Phillip T. Hawkins, Timothy A.J. Haystead, Xiao-lin He, Claus W. Heizmann, Carl-Henrik Heldin, Michelle L. Hermiston, Peter Herrlich, Elizabeth A. Hewat, Bertil Hille, Douglas J. Hilton, K.A. Hinchliffe, Steffan N. Ho, Su-Chin Ho, Mark Hochstrasser, Franz Hofmann, Christopher W. Hogue, Wim G.J. Hol, Jocelyn Holash, Robert A. Holmgren, Barry Honig, Bruce S. Hostager, Stevan R. Hubbard, Michael Huber, Tony Hunter, Anna Huttenlocher, Sarah G. Hymowitz, James N. Ihle, Jean-Luc Imler, R.F. Irvine, Ehud Y. Isacoff, Xavier Iturrioz, Lars F. Iversen, Ravi Iyengar, Stephen P. Jackson, Lily Yeh Jan, Fabiola Janiak-Spens, Paul A. Janmey, Peter Gildsig Jansen, Sophie Jarriault, Jonathan A. Javitch, Elwood V. Jensen, Kristen Jepsen, E. Yvonne Jones, Katherine A. Jones, J. Dedrick Jordan, Jomon Joseph, Louis B. Justement, Yariv Kafri, Richard A. Kahn, Shin W. Kang, Arthur Karlin, Heidi R. Kast-Woelbern, Randal J. Kaufman, Andrius Kazlauskas, James H. Keen, Rolf Kemler, Bruce E. Kemp, Mary B. Kennedy, Matthew A. Kennedy, Ushio Kikkawa, Albert H. Kim, Soo-A Kim, Sung-Hou Kim, Youngjoo Kim, Kirst King-Jones, Chris Kintner, Saul Kivimäe, Claude B. Klee, Rüdiger Klein, Thomas Kleppisch, Steven A. Kliewer, Richard A. Klinghoffer, Juergen A. Knoblich, Bostjan Kobe, George Kochs, Monica Kong-Beltran, Rolf König, Albert C. Koong, Murray Korc, Daniel Kornitzer, Anthony A. Kossiakoff, Jun Kotera, M.V. Kovalenko, Tohru Kozasa, Sergei Kozlov, Keith G. Kozminski, Sonja Krugmann, John Kuriyan, Riki Kurokawa, Peter D. Kwong, Wi S. Lai, Elise Lamar, Millard H. Lambert, David G. Lambright, Doron Lancet, Reiko Landry, Wallace Y. Langdon, Lorene K. Langeberg, Paul Lasko, Vaughn Latham, Martin F. Lavin, Kevin A. Lease, Hakon Leffler, Mark A. Lemmon, Ann E. Leonard, Alexander Levitzki, Hong-Jun Liao, Lucy Liaw, Giordano Liberi, Heiko Lickert, Robert C. Liddington, Thomas M. Lincoln, Jürgen U. Linder, Maurine E. Linder, Hui Liu, Zhengchang Liu, Marja K. Lohela, Sarah H. Louie, Deirdre K. Luttrell, Louis M. Luttrell, Karen M. Lyons, S. Lance Macaulay, Michael Maceyka, Thomas Maciag, Fernando Macian, Carol MacKintosh, David H. MacLennan, Nadir A. Mahmood, Craig C. Malbon, Sohail Malik, Orna Man, Carol L. Manahan, Anna Mandinova, Vincent C. Manganiello, James L. Manley, Matthias Mann, Gerald Manning, Ed Manser, Marta Margeta-Mitrovic, Robert F. Margolskee, Julia Marinissen, Roy A. Mariuzza, Mina D. Marmor, G. Steven Martin, Karen H. Martin, Sergio E. Martinez, Michael B. Mathews, Bruce J. Mayer, Mark L. Mayer, Maria R. Mazzoni, Frank McCormick, Clare H. McGowan, Melissa M. McKay, Wallace L. McKeehan, Alison J. McLean, Anthony R. Means, Ruedi Meili, Jingwei Meng, Mark Merchant, Frank Mercurio, Graeme Milligan, Guo-Li Ming, Daniel L. Minor, Nadeem Moghal, Neils Peter H. Møller, Marco Mongillo, Marc Montminy, Randall T. Moon, Richard I. Morimoto, Stephen E. Moss, Helen R. Mott, Carla Mouta, Marco Muda, Marc C. Mumby, Gretchen A. Murphy, Marco Muzi-Falconi, Raghavendra Nagaraj, Stefan R. Nahorski, Angus C. Nairn, Piers Nash, Benjamin G. Neel, Alexandra C. Newton, Yasutomi Nishizuka, Joseph P. Noel, Ellen A.A. Nollen, Irene M.A. Nooren, Rodney O'Connor, Stefan Offermanns, Tsviya Olender, Shao-En Ong, Darerca Owen, Lisa J. Pagliari, Lily Pao, John Papaconstantinou, Leonardo Pardo, Hay-Oak Park, Young Chul Park, Peter J. Parker, J. Thomas Parsons, J.M. Passner, Tony Pawson, Achille Pelliccioli, J. Regino Perez-Polo, Norbert Perrimon, Fabrice G. Petite, Emmanuel Petroulakis, Samuel L. Pfaff, Jacob Piehler, Linda J. Pike, Michael J. Pinkoski, Fiona J. Pixley, Paolo Plevani, Mu-ming Poo, Tullioi Pozzan, Stephen M. Prescott, Igor Prudovsky, James W. Putney, Thomas Radimerski, Elzbieta Radzio-Andzelm, Prahlad T. Ram, Lucia Rameh, Danica Ramljak, Barbara Ranscht, Anjana Rao, Carol J. Raport, Jacqueline D. Reeves, Holger Rehman, Trevor W. Reichman, Eric Reiter, Michael A. Resnick, Michael Reth, Sue Goo Rhee, Joel D. Richter, Rodney L. Rietze, James M. Rini, Jürgen A. Ripperger, Josep Rizo, Janet D. Robishaw, H. Llewelyn Roderick, Robert G. Roeder, Larry R. Rohrschneider, David Ron, Michael G. Rosenfeld, Hans Rosenfeldt, Kent L. Rossman, Christopher B. Roth, Markus G. Rudolph, Anja Ruppelt, Lino Saez, Thomas P. Sakmar, Guy S. Salvesen, Paolo Sassone-Corsi, Charles L. Saxe, Beat W. Schäfer, Ueli Schibler, Christian W. Schindler, Tobias Schmelzle, Sandra L. Schmid, Anja Schmidt, Eric F. Schmidt, Gideon Schreiber, Joachim E. Schultz, Beat Schwaller, Klaus Schwamborn, Thue Schwartz, William F. Schwindinger, Giorgio Scita, John D. Scott, Shaun Scott, Thomas Seebeck, Charles N. Serhan, John B. Shabb, Andrey S. Shaw, Stephen B. Shears, Shirish Shenolikar, Lei Shi, Chanseok Shin, Kazuhiro Shiozaki, Kevan M. Shokat, Trevor J. Shuttleworth, David P. Siderovski, Steven A. Siegelbaum, Adam M. Silverstein, Robert H. Singer, Michael K. Skinner, Jill K. Slack-Davis, Stephen J. Smerdon, Graeme C.M. Smith, Guillaume Smits, Sarah M. Smolik, Jessica E. Smotrys, Emer M. Smyth, Jason T. Snyder, Naoko Sogame, Raffaella Soldi, John Sondek, Nahum Sonenberg, Erica Dutil Sonneberg, Lindsay G. Sparrow, Sarah Spiegel, Stephen R. Sprang, Deepak Srivastava, Robyn L. Stanfield, E. Richard Stanley, Deborah J. Stauber, Christopher Stefan, Lena Stenson-Holst, Len Stephens, Paul W. Sternberg, Paul C. Sternweis, Ruth Steward, John T. Stickney, Andrew W. Stoker, Stephen M. Strittmatter, Beth E. Stronach, Roland K. Strong, Robert M. Stroud, Thomas C. Südhof, Roger K. Sunahara, Brian J. Sutton, Sipeki Szabolcs, Xiao-Bo Tang, Kjetil Taskén, Hisashi Tatebe, Servane Tauszig-Delamasure, Colin W. Taylor, Garry L. Taylor, Laura J. Taylor, Susan S. Taylor, George Thomas, Robert P. Thomas, E. Brad Thompson, Michael J. Thompson, Janet M. Thornton, Carl S. Thummel, Hideaki Togashi, Amy Hin Yan Tong, Nicholas K. Tonks, Peter Tontonoz, M.K. Topham, Knut Martin Torgersen, Hien Tran, Michel L. Tremblay, Ming-Jer Tsai, Sophia Y. Tsai, Susan Tsunoda, Stewart Turley, Darren Tyson, Robert L. Van Etten, Gilbert Vassart, Peter J. Verveer, Virginie Vlaeminck, Abraham M. de Vos, Ty C. Voss, Robert Walczak, Graham C. Walker, John C. Walker, Gernot Walter, Mark R. Walter, Fen Wang, Jean Y.J. Wang, Weiru Wang, Richard J. Ward, Philip Wedegaertner, Christian Wehrle, Arthur Weiss, Jamie L. Weiss, Alan Wells, Claudia Werner, Ann H. West, Marie C. Weston, John K. Westwick, Anders Wetterholm, Morris F. White, Malcolm Whitman, Matt R. Whorton, Christian Wiesmann, Roger L. Williams, William D. Willis, Timothy M. Willson, Ian A. Wilson, Ofer Wiser, Matthew J. Wishart, Alfred Wittinghofer, James R. Woodgett, David K. Worthylake, Jeffrey L. Wrana, Hao Wu, Yijin Xiao, H. Eric Xu, Yan Xu, Zheng Xu, Michael B. Yaffe, Kenneth M. Yamada, Seun-Ah Yang, Wannian Yang, Yosef Yarden, Hong Ye, Weilan Ye, Todd O. Yeates, Helen L. Yin, John D. York, Edgar C. Young, Kenneth W. Young, Matthew A. Young, Michael W. Young, Minmin Yu, Nathan R. Zaccai, Manuela Zaccolo, Eli Zamir, Mark von Zastrow, Chao Zhang, Xuewu Zhang, Zhong-Yin Zhang, Wenhong Zhou, and Roya Zoraghi

Published

2003

23. The Influence of Cellular Location on Ras Function

Author

Michelle A. Booden, Janice E. Buss, and John T. Stickney

Subjects

Chemistry, Function (mathematics), Neuroscience

Published

2003

24. Targeting proteins to membranes, using signal sequences for lipid modifications

Author

John T. Stickney, Michelle A. Booden, and Janice E. Buss

Published

2001

25. Mutation of Ha-Ras C terminus changes effector pathway utilization

Author

Michelle A. Booden, Donald S. Sakaguchi, and Janice E. Buss

Subjects

GTP', Neurite, CDC42, Biology, Biochemistry, Models, Biological, PC12 Cells, chemistry.chemical_compound, Phosphatidylinositol 3-Kinases, Neurites, Animals, Phosphatidylinositol, Cytoskeleton, Molecular Biology, Neurons, Effector, Kinase, Cell Differentiation, Cell Biology, Actins, Cell biology, Rats, Proto-Oncogene Proteins c-raf, chemistry, Mutation, ras Proteins, Lamellipodium, Signal Transduction

Abstract

In PC12 cells, Ha-Ras modulates multiple effector proteins that induce neuronal differentiation. To regulate these pathways Ha-Ras must be located at the plasma membrane, a process normally requiring attachment of farnesyl and palmitate lipids to the C terminus. Ext61L, a constitutively activated and palmitoylated Ha-Ras that lacks a farnesyl group, induced neurites with more actin cytoskeletal changes and lamellipodia than were induced by farnesylated Ha-Ras61L. Ext61L-triggered neurite outgrowth was prevented easily by co-expressing inhibitory Rho, Cdc42, or p21-activated kinase but required increased amounts of inhibitory Rac. Compared with Ha-Ras61L, Ext61L caused 2-fold greater Rac GTP binding and phosphatidylinositol 3-kinase activity in membranes, a hyperactivation that explained the numerous lamellipodia and ineffectiveness of Rac(N17). In contrast, Ext61L activated B-Raf kinase and ERK phosphorylation more poorly than Ha-Ras61L. Thus, accentuated differentiation by Ext61L apparently results from heightened activation of one Ras effector (phosphatidylinositol 3-kinase) and suboptimal activation of another (B-Raf). This surprising unbalanced effector activation, without changes in the designated Ras effector domain, indicates the Ext61L C-terminal alternations are a new way to influence Ha-Ras-effector utilization and suggest a broader role of the lipidated C terminus in Ha-Ras biological functions.

Published

2000

26. Analysis of function and regulation of proteins that mediate signal transduction by use of lipid-modified plasma membrane-targeting sequences

Author

Geoffrey J. Clark, Lawrence A. Quilliam, Janice E. Buss, Channing J. Der, and Gary W. Reuther

Subjects

Signal peptide, Biochemistry, GTPase-activating protein, biology.protein, Signal transducing adaptor protein, Biology, Signal transduction, Fusion protein, Receptor tyrosine kinase, SH3 domain, Myristoylation, Cell biology

Abstract

It is now established that the function of many signaling molecules is controlled, in part, by regulation of subcellular localization. For example, the dynamic recruitment of normally cytosolic proteins to the plasma membrane, by activated Ras or activated receptor tyrosine kinases, facilitates their interaction with other membrane-associated components that participate in their full activation (e.g., Raf-1). Therefore, the creation of chimeric proteins that contain lipid-modified signaling sequences that direct membrane localization allows the generation of constitutively activated variants of such proteins. The amino-terminal myristoylation signal sequence of Src family proteins and the carboxy-terminal prenylation signal sequence of Ras proteins have been widely used to achieve this goal. Such membrane-targeted variants have proved to be valuable reagents in the study of the biochemical and biological properties of many signaling molecules.

Published

2000

27. A Non-farnesylated Ha-Ras Protein Can Be Palmitoylated and Trigger Potent Differentiation and Transformation

Author

Steven G. Punke, Patricia A. Solski, Janice E. Buss, Tara L. Baker, Channing J. Der, and Michelle A. Booden

Subjects

DNA, Complementary, GTP', Cellular differentiation, Palmitic Acid, Protein Prenylation, Transfection, Biochemistry, Guanosine Diphosphate, PC12 Cells, environment and public health, Mice, Structure-Activity Relationship, Palmitoylation, Prenylation, Structure–activity relationship, Animals, Cysteine, Molecular Biology, Chemistry, Cell Membrane, Biological activity, Cell Differentiation, Cell Biology, 3T3 Cells, Rats, ras Proteins, Protein prenylation, lipids (amino acids, peptides, and proteins), Guanosine Triphosphate

Abstract

Ha-Ras undergoes post-translational modifications (including attachment of farnesyl and palmitate) that culminate in localization of the protein to the plasma membrane. Because palmitate is not attached without prior farnesyl addition, the distinct contributions of the two lipid modifications to membrane attachment or biological activity have been difficult to examine. To test if palmitate is able to support these crucial functions on its own, novel C-terminal mutants of Ha-Ras were constructed, retaining the natural sites for palmitoylation, but replacing the C-terminal residue of the CAAX signal for prenylation with six lysines. Both the Ext61L and ExtWT proteins were modified in a dynamic fashion by palmitate, without being farnesylated; bound to membranes modestly (40% as well as native Ha-Ras); and retained appropriate GTP binding properties. Ext61L caused potent transformation of NIH 3T3 cells and, unexpectedly, an exaggerated differentiation of PC12 cells. Ext61L with the six lysines but lacking palmitates was inactive. Thus, farnesyl is not needed as a signal for palmitate attachment or removal, and a combination of transient palmitate modification and basic residues can support Ha-Ras membrane binding and two quite different biological functions. The roles of palmitate can therefore be independent of and distinct from those of farnesyl. Reciprocally, if membrane association can be sustained largely through palmitates, farnesyl is freed to interact with other proteins.

Published

1999

28. Murine GBP-2: a new IFN-gamma-induced member of the GBP family of GTPases isolated from macrophages

Author

Janice E. Buss, Vinod Asundi, Deborah J. Vestal, Neal G. Copeland, Nancy A. Jenkins, Richard A. Maki, Scott R. McKercher, and Gregory S. Kelner

Subjects

Immunology, Molecular Sequence Data, Protein Prenylation, Muri, GTPase, Biology, GTP Phosphohydrolases, Interferon-gamma, Mice, Interferon, GTP-Binding Proteins, Virology, medicine, Animals, Humans, Amino Acid Sequence, Cloning, Molecular, Cells, Cultured, Sequence Homology, Amino Acid, Macrophages, Chromosome Mapping, Cell Biology, Molecular biology, Mice, Inbred C57BL, Enzyme Induction, Multigene Family, COS Cells, Ifn gamma, medicine.drug

Abstract

We have cloned a new member of the interferon (IFN)-induced guanylate-binding protein (GBP) family of GTPases, murine GBP-2 (mGBP-2), from bone marrow-derived macrophages. mGBP-2 is located on murine chromosome 3, where it is linked to mGBP-1. With the identification of mGBP-2 there are now two human and two murine GBPs. Like other GBPs, mGBP-2 RNA and protein are induced by IFN-gamma. In addition, mGBP-2 shares with the other GBPs important structural features that distinguish this family from other GTPases. First, mGBP-2 contains only two of the three consensus sequences for nucleotide binding found within the classic GTP binding regions of other GTPases. A second amino acid motif found in mGBP-2 is a potential C-terminal site for isoprenoid modification, called a CaaX sequence. mGBP-2 is prenylated, as detected by [3H]mevalonate incorporation, when expressed in COS cells and preferentially incorporates the C-20 isoprenoid geranylgeraniol. Surprisingly, despite having a functional CaaX sequence, mGBP-2 is primarily cytosolic. GBP proteins are very abundant in IFN-exposed cells, but little is known about their function. mGBP-2 is expressed by IFN-gamma-treated cells from C57Bl/6 mice, whereas mGBP-1 is not. Thus, the identification of mGBP-2 makes possible the study of GBP function in the absence of a second family member.

Published

1998

29. Prenylation of an interferon-gamma-induced GTP-binding protein: the human guanylate binding protein, huGBP1

Author

John T. Stickney, David E. Nantais, Martin Schwemmle, Janice E. Buss, and Deborah J. Vestal

Subjects

G protein, Immunology, Protein Prenylation, Mevalonic Acid, HL-60 Cells, Biology, Transfection, Tritium, DNA-binding protein, Guanylate-binding protein, chemistry.chemical_compound, Benzodiazepines, Interferon-gamma, Geranylgeraniol, Prenylation, GTP-Binding Proteins, Immunology and Allergy, Animals, Humans, Enzyme Inhibitors, COS cells, organic chemicals, Farnesyl Transferase Inhibitor, Cell Biology, Biochemistry, chemistry, COS Cells, lipids (amino acids, peptides, and proteins), Oligopeptides

Abstract

Interferons (IFN) and lipopolysaccharide (LPS) cause multiple changes in isoprenoid-modified proteins in murine macrophages, the most dramatic being the expression of a prenyl protein of 65 kDa. The guanylate binding proteins (GBPs) are IFN-inducible GTP-binding proteins of ~65 kDa that possess a CaaX motif at their C-terminus, indicating that they might be substrates for prenyltransferases. The human GBP1 protein, when expressed in transfected COS-1 cells, incorporates radioactivity from the isoprenoid precursor [3H]mevalonate. In addition, huGBPs expressed from the endogenous genes in IFN-γ-treated human fibroblasts or monocytic cells were also found to be isoprenoid modified. IFN-γ-induced huGBPs in HL-60 cells were not labeled by the specific C20 isoprenoid, [3H]geranylgeraniol, but did show decreased isoprenoid incorporation in cells treated with the farnesyl transferase inhibitor BZA5B, indicating that huGBPs in HL-60 cells are probably modified by a C15 farnesyl rather than the more common C20lipid. Differentiated HL-60 cells treated with IFN-γ/LPS showed no change in the profile of constitutive isoprenylated proteins and the IFN-γ/LPS-induced huGBPs remained prenylated. Despite being prenylated, huGBP1 in COS cells and endogenous huGBPs in HL-60 cells were primarily (~85%) cytosolic. Human GBPs are thus among the select group of prenyl proteins whose synthesis is tightly regulated by a cytokine. HuGBP1 is an abundant protein whose prenylation may be vulnerable to farnesyl transferase inhibitors that are designed to prevent farnesylation of Ras proteins.

Published

1996

30. Rat p67 GBP is induced by interferon-gamma and isoprenoid-modified in macrophages

Author

Vinod Asundi, Gregory S. Kelner, Dominique Maciejewski, Janice E. Buss, Richard A. Maki, and Deborah J. Vestal

Subjects

Lipopolysaccharides, Immunoblotting, Molecular Sequence Data, Biophysics, Protein Prenylation, Mevalonic Acid, Bone Marrow Cells, Biology, Biochemistry, Polymerase Chain Reaction, Rats, Sprague-Dawley, Interferon-gamma, GTP-binding protein regulators, Prenylation, Interferon, GTP-Binding Proteins, medicine, Animals, Interferon gamma, Molecular Biology, Cells, Cultured, DNA Primers, COS cells, Microglia, Base Sequence, Macrophages, Cell Biology, Transfection, Molecular biology, Rats, Molecular Weight, medicine.anatomical_structure, Animals, Newborn, Protein prenylation, medicine.drug

Abstract

The guanylate binding proteins, GBPs, are a family of interferon-induced GTP-binding proteins that include the rat p67. We report here that rat p67, for which interferon regulation had not previously been demonstrated, is induced by IFN-gamma and also by LPS in both cultured bone marrow-derived macrophages and microglia. The basal level of rat p67 in macrophages is low but increases dramatically between 2 and 4 hours after treating cells with either IFN-gamma or LPS. It then remains elevated over the next 24 hours. Rat p67 is isoprenoid modified. The isoprenoid modification was detected in p67 isolated both from primary IFN-gamma-activated macrophages and when the gene for p67 was transfected into COS cells. This is the first demonstration of in vivo prenylation of a GBP. The interferon regulation and prenylation of rat p67 point toward this protein being significant in the functions of both activated macrophages and microglia.

Published

1996

31. Induction of a prenylated 65-kd protein in macrophages by interferon or lipopolysaccharide

Author

Janice E. Buss, Richard A. Maki, and Deborah J. Vestal

Subjects

Lipopolysaccharides, Lipopolysaccharide, medicine.medical_treatment, Immunology, Protein Prenylation, Bone Marrow Cells, Biology, Monocytes, chemistry.chemical_compound, Benzodiazepines, Interferon-gamma, Mice, Prenylation, Interferon, Transferases, medicine, Tumor Cells, Cultured, Immunology and Allergy, Macrophage, Animals, Farnesyltranstransferase, Enzyme Inhibitors, Growth Substances, Mice, Inbred BALB C, Alkyl and Aryl Transferases, Macrophages, Farnesyltransferase inhibitor, Cell Biology, Macrophage Activation, Protein-Tyrosine Kinases, Genistein, Isoflavones, Cell biology, Mice, Inbred C57BL, Molecular Weight, Cytokine, chemistry, Protein prenylation, lipids (amino acids, peptides, and proteins), Macrophage proliferation, Oligopeptides, medicine.drug

Abstract

Treatment of murine bone marrow-derived macrophages with interferon-γ (IFN-γ) and/or lipopolysaccharide (LPS) resulted in changes in the abundance of a number of prenylated proteins. The most significant change involved a protein of 65 kd (p65) that became one of the most abundant prenylated proteins following treatment. The 65-kd protein was induced by agents that stimulate macrophage activation (IFNs or LPS) but not by cytokines that promote macrophage proliferation, such as granulocyte-macrophage colony-stimulating factor (GM-CSF), M-CSF, or interleukin-3. The majority of p65 was localized to subcellular fractions containing internal and plasma membranes but was not detected in nuclear membranes. The farnesyltransferase inhibitor BZA-5B caused a dramatic decrease in p65 prenylation, suggesting that this protein may be modified by the C15 isoprenoid farnesyl. These observations provide the first direct evidence that interferons and LPS cause changes in the abundance of specific isoprenoid-modified proteins in macrophages.

Published

1995

32. [33] Targeting proteins to membranes using signal sequences for lipid modification

Author

Patricia A. Solski, Janice E. Buss, Channing J. Der, Sarah G. Coats, and Lawrence A. Quilliam

Subjects

Protein Sorting Signals, Membrane, Biochemistry, Membrane protein, Protein targeting, Peripheral membrane protein, medicine, Protein prenylation, Plasma protein binding, Biology, medicine.disease_cause, Plant lipid transfer proteins, Cell biology

Abstract

Covalent attachment of lipids appears to be an important mechanism by which many proteins interact with membranes. As we learn more about how lipids and adjacent amino acids participate in addressing proteins to specific membranes within the cell, it should be possible to design more elegant and precise membrane targeting systems that can be used to guide proteins to functionally relevant destinations.

Published

1995

33. Polylysine domain of K-ras 4B protein is crucial for malignant transformation

Author

J H Jackson, Charles G. Cochrane, J. W. Li, Janice E. Buss, and Channing J. Der

Subjects

Molecular Sequence Data, Protein Prenylation, Biology, In Vitro Techniques, Methylation, Cell membrane, Proto-Oncogene Proteins p21(ras), chemistry.chemical_compound, Mice, Structure-Activity Relationship, Prenylation, medicine, Structure–activity relationship, Animals, Amino Acid Sequence, Multidisciplinary, C-terminus, Lysine, Cell Membrane, 3T3 Cells, Cell Compartmentation, Rats, medicine.anatomical_structure, Cell Transformation, Neoplastic, chemistry, Biochemistry, Polylysine, Biophysics, Mutagenesis, Site-Directed, Protein prenylation, Protein Processing, Post-Translational, Binding domain, Research Article

Abstract

Previous studies have shown that posttranslational modifications are required for both oncogenic K-ras 4B protein membrane binding and transforming activity. In addition, Hancock et al. [Hancock, J. F., Patterson, H. & Marshall, C. J. (1990) Cell 63, 133-139] found that a polylysine domain contained at the C terminus of K-ras 4B was also absolutely essential for K-ras 4B membrane binding but, surprisingly, neither the polylysine domain nor membrane binding was required for transforming activity. We have performed similar studies, but our results are distinctly different. Our studies indicate that the polylysine domain is crucial for K-ras 4B transforming activity. Moreover, we demonstrate that although the polylysine domain increases K-ras 4B membrane binding, significant amounts of membrane binding can occur in the absence of this domain. Finally, while our studies are consistent with the notion that membrane binding is required for K-ras 4B transforming activity, we show that membrane binding, in and of itself, is not sufficient for efficient K-ras 4B transforming activity.

Published

1994

34. Specific isoprenoid modification is required for function of normal, but not oncogenic, Ras protein

Author

Adrienne D. Cox, Janice E. Buss, Mark M. Hisaka, and Channing J. Der

Subjects

Mutant, Molecular Sequence Data, Proto-Oncogene Proteins pp60(c-src), Biology, environment and public health, SH3 domain, 3T3 cells, Gene product, Proto-Oncogene Proteins p21(ras), chemistry.chemical_compound, Mice, Structure-Activity Relationship, Mutant protein, GTP-Binding Proteins, medicine, Animals, Amino Acid Sequence, Cysteine, Molecular Biology, Cell Membrane, Cell Biology, 3T3 Cells, Farnesol, In vitro, body regions, medicine.anatomical_structure, Cell Transformation, Neoplastic, rap GTP-Binding Proteins, chemistry, Biochemistry, Mutagenesis, Site-Directed, Growth inhibition, Diterpenes, Protein Processing, Post-Translational, Cell Division, Proto-oncogene tyrosine-protein kinase Src, Research Article

Abstract

While the Ras C-terminal CAAX sequence signals modification by a 15-carbon farnesyl isoprenoid, the majority of isoprenylated proteins in mammalian cells are modified instead by a 20-carbon geranylgeranyl moiety. To determine the structural and functional basis for modification of proteins by a specific isoprenoid group, we have generated chimeric Ras proteins containing C-terminal CAAX sequences (CVLL and CAIL) from geranylgeranyl-modified proteins and a chimeric Krev-1 protein containing the H-Ras C-terminal CAAX sequence (CVLS). Our results demonstrate that both oncogenic Ras transforming activity and Krev-1 antagonism of Ras transforming activity can be promoted by either farnesyl or geranylgeranyl modification. Similarly, geranylgeranyl-modified normal Ras [Ras(WT)CVLL], when overexpressed, exhibited the same level of transforming activity as the authentic farnesyl-modified normal Ras protein. Therefore, farnesyl and geranylgeranyl moieties are functionally interchangeable for these biological activities. In contrast, expression of moderate levels of geranylgeranyl-modified normal Ras inhibited the growth of untransformed NIH 3T3 cells. This growth inhibition was overcome by coexpression of the mutant protein with oncogenic Ras or Raf, but not with oncogenic Src or normal Ras. The similar growth-inhibiting activities of Ras(WT)CVLL and the previously described Ras(17N) dominant inhibitory mutant suggest that geranylgeranyl-modified normal Ras may exert its growth-inhibiting action by perturbing endogenous Ras function. These results suggest that normal Ras function may specifically require protein modification by a farnesyl, but not a geranylgeranyl, isoprenoid.

Published

1992

35. Isoprenoid modification of rab proteins terminating in CC or CXC motifs

Author

Adrienne D. Cox, Janice E. Buss, Michael Sinensky, Robert J. Lutz, Leah B Conroy, William E. Balch, Channing J. Der, Jeffrey R. Bourne, and Roya Khosravi-Far

Subjects

Insecta, rab3 GTP-Binding Proteins, Prenyltransferase, Mevalonic Acid, Nerve Tissue Proteins, Biology, Cell Line, Geranylgeranylation, Prenylation, Polyisoprenyl Phosphates, Mutant protein, GTP-Binding Proteins, Cricetinae, Escherichia coli, Animals, Amino Acid Sequence, Codon, chemistry.chemical_classification, Multidisciplinary, Recombinant Proteins, Amino acid, rab1 GTP-Binding Proteins, Membrane protein, Biochemistry, chemistry, Rab, Protein Processing, Post-Translational, Cysteine, Research Article

Abstract

Mevalonate starvation of hamster fibroblasts resulted in a shift of rab1b from the membrane to the cytosolic fraction, suggesting that rab1b depends upon an isoprenoid modification for its membrane localization. rab1b and rab3a proteins expressed in insect cells incorporated a product of [3H]mevalonate, and gas chromatography analysis of material released by Raney nickel cleavage demonstrated that rab1b and rab3a are modified by geranylgeranyl groups. Additionally, in vitro prenylation analysis demonstrated farnesyl modification of H-ras but geranylgeranyl modification of five rab proteins (1a, 1b, 2, 3a, and 6). Together, these results suggest that the carboxyl-terminal CC/CXC motifs (X = any amino acid) specifically signal for addition of geranylgeranyl, but not farnesyl, groups. A rab1b mutant protein lacking the two carboxyl-terminal cysteine residues was not prenylated in vitro. However, since a mutant H-ras protein that terminates with tandem cysteine residues was also not modified, the CC motif may be essential, but not sufficient, to signal prenylation of rab1b. Finally, rab1b and rab3a proteins were not efficient substrates for either farnesyl- or geranylgeranyltransferase activities that modify CAAX-containing proteins (A = any aliphatic amino acid). Therefore, rab proteins may be modified by a prenyltransferase(s) distinct from the prenyltransferases that modify carboxyl-terminal CAAX proteins.

Published

1991

36. Farnesol modification of Kirsten-ras exon 4B protein is essential for transformation

Author

Channing J. Der, Jeffrey R. Bourne, Patricia A. Solski, J H Jackson, Janice E. Buss, and Charles G. Cochrane

Subjects

Genetic Vectors, Mevalonic Acid, Biology, Transfection, Cell Line, Gene product, Proto-Oncogene Proteins p21(ras), chemistry.chemical_compound, Mice, Prenylation, Palmitoylation, Proto-Oncogene Proteins, Animals, Humans, Lovastatin, Cells, Cultured, Multidisciplinary, Oncogene, Anticholesteremic Agents, Farnesol, Exons, Cytosol, Cell Transformation, Neoplastic, chemistry, Biochemistry, Mutation, lipids (amino acids, peptides, and proteins), Oligonucleotide Probes, Research Article

Abstract

Oncogenic forms of ras proteins are synthesized in the cytosol and must become membrane associated to cause malignant transformation. Palmitic acid and an isoprenoid (farnesol) intermediate in cholesterol biosynthesis are attached to separate cysteine residues near the C termini of H-ras, N-ras, and Kirsten-ras (K-ras) exon 4A-encoded proteins. These lipid modifications have been suggested to promote or stabilize the association of ras proteins with membranes. Because preventing isoprenylation also prevents palmitoylation, examining the importance of isoprenylation alone has not been possible. However, the oncogenic human [Val12]K-ras 4B protein is not palmitoylated but is isoprenylated, membrane associated, and fully transforming. We therefore constructed mutant [Val12]K-ras 4B proteins that were not isoprenylated to examine the effects of isoprenylation in the absence of palmitoylation. The nonisoprenylated mutant proteins both failed to associate with membranes and did not transform NIH 3T3 cells. In addition, inhibition of isoprenoid and cholesterol synthesis with the drug compactin also decreased [Val12]K-ras 4B protein isoprenylation and membrane association. These results unequivocally demonstrate that isoprenylation, rather than palmitoylation, is essential for ras membrane binding and ras transforming activity. These findings clearly indicate the biological significance of ras protein modification by farnesol and suggest that this modification may be important for facilitating the processing, trafficking, and biological activity of other isoprenylated proteins. Because K-ras is the most frequently activated oncogene in a wide spectrum of human malignancies, study of this pathway could lead to important therapeutic treatments.

Published

1990

37. Oxidative modification of H-ras: S-thiolation and S-nitrosylation of reactive cysteines

Author

Robert J. Mallis, James A. Thomas, and Janice E. Buss

Subjects

Iodoacetic acid, Oxidative phosphorylation, Oncogene Protein p21(ras), Biochemistry, Mice, chemistry.chemical_compound, Cystamine, Animals, Cysteine, Sulfhydryl Compounds, Hydrogen peroxide, Molecular Biology, chemistry.chemical_classification, 3T3 Cells, Cell Biology, Glutathione, S-Nitrosylation, Precipitin Tests, chemistry, Thiol, Electrophoresis, Polyacrylamide Gel, Oxidation-Reduction, Nitroso Compounds, Research Article

Abstract

The reactive cysteines in H-ras are subject to oxidative modifications that potentially alter the cellular function of this protein. In this study, purified H-ras was modified by thiol oxidants such as hydrogen peroxide (H2O2), S-nitrosoglutathione, diamide, glutathione disulphide (GSSG) and cystamine, producing as many as four charge-isomeric forms of the protein. These results suggest that all four reactive cysteines of H-ras are potential sites of regulatory modification reactions. S-nitrosylated and S-glutathiolated forms of H-ras were identified by protocols that depend on separation of alkylated proteins on electrofocusing gels. S-nitrosoglutathione could S-nitrosylate H-ras on four cysteine residues, while reduced glutathione (GSH) and H2O2 mediate S-glutathiolation on at least one cysteine of H-ras. Either GSSG or diamide S-glutathiolated at least two cysteine residues of purified H-ras. Iodoacetic acid reacts with three cysteine residues. In intact NIH-3T3 cells, wild-type H-ras was S-glutathiolated by diamide. Similarly, cells expressing a C118S mutant or a C181S/C184S double mutant of H-ras were S-glutathiolated by diamide. These results suggest that H-ras can be S-glutathiolated on multiple thiols in vivo and that at least one of these thiols is normally lipid-modified. In cells treated with S-nitrosocysteine, evidence for both S-nitrosylated and S-glutathiolated H-ras was obtained and S-nitrosylation was the predominant modification. These results show that oxidative modification of H-ras can be extensive in vivo, that both S-nitrosylated and S-glutathiolated forms may be important, and that oxidation may occur on reactive cysteines that are normally targeted for lipid-modification reactions.

Published

2001

38. Sarkosyl activation of RNA polymerase activity in mitotic mouse cells

Author

Janice E. Buss, Patricio Gariglio, and Melvin H. Green

Subjects

Time Factors, Transcription, Genetic, Uracil Nucleotides, Detergents, Biophysics, Mitosis, RNA-dependent RNA polymerase, Thymus Gland, Biology, Tritium, Peptides, Cyclic, Biochemistry, Polyethylene Glycols, Mice, chemistry.chemical_compound, Tissue culture, Structural Biology, RNA polymerase, Genetics, Animals, Uridine, Molecular Biology, Cells, Cultured, Mice, Inbred BALB C, Basidiomycota, Fatty Acids, Demecolcine, Dimethylformamide, Sarcosine, DNA, DNA-Directed RNA Polymerases, Templates, Genetic, Cell Biology, Metabolism, Mycotoxins, Rifamycins, Cell biology, Kinetics, chemistry, Isotope Labeling, Cattle, Spectrophotometry, Ultraviolet, Oligopeptides, Cell Division

Published

1974

39. The six amino-terminal amino acids of p60src are sufficient to cause myristylation of p21v-ras

Author

Channing J. Der, Janice E. Buss, and Patricia A. Solski

Subjects

chemistry.chemical_classification, Myristic acid, Cell Biology, Biology, Amino acid, Serine, chemistry.chemical_compound, Residue (chemistry), chemistry, Biochemistry, Glycine, Protein biosynthesis, Oncogene Protein p21(ras), Molecular Biology, Peptide sequence

Abstract

We have used oligonucleotide-directed mutagenesis to replace the N-terminal amino acids of p21v-ras with residues which mimic the amino terminus of p60v-src. p21v-ras protein possessing only the first five amino acids of p60src was not myristylated, while substitution of residue 6 (serine) produced a protein p21(GSSKS) which incorporated [3H]myristic acid that was stable to hydroxylamine, sensitive to inhibitors of protein synthesis, and found in both the normally nonacylated precursor and mature forms of p21(GSSKS). This defines the minimum framework of the p60v-src myristylation signal (glycine 2 and serine 6) and identifies serine 6 as a crucial part of that signal for myristylation of a protein in vivo.

Published

1988

40. The absence of myristic acid decreases membrane binding of p60src but does not affect tyrosine protein kinase activity

Author

Janice E. Buss, K Gould, Mark P. Kamps, and Bartholomew M. Sefton

Subjects

animal structures, Immunology, Retroviridae Proteins, Chick Embryo, Protein tyrosine phosphatase, Biology, Myristic Acid, Microbiology, SH3 domain, Oncogene Protein pp60(v-src), Virology, Animals, Protein phosphorylation, Phosphorylation, Tyrosine, Protein kinase A, Cells, Cultured, Protein Kinase C, Protein kinase C, Kinase, Cell Membrane, Peripheral membrane protein, Protein-Tyrosine Kinases, Cell Transformation, Viral, Cell Transformation, Neoplastic, Avian Sarcoma Viruses, Biochemistry, Insect Science, Mutation, Myristic Acids, Research Article

Abstract

We have constructed two point mutants of Rous sarcoma virus in which the amino-terminal glycine residue of the transforming protein, p60src, was changed to an alanine or a glutamic acid residue. Both mutant proteins failed to become myristylated and, more importantly, no longer transformed cells. The lack of transformation could not be attributed to defects in the catalytic activity of the mutant p60src proteins. In vitro phosphorylation of the peptide angiotensin or of the cellular substrate proteins enolase and p36 revealed no significant differences in the Km or specific activity of the mutant and wild-type p60src proteins. However, when cellular fractions were prepared, less than 12% of the nonmyristylated p60src proteins was bound to membranes. In contrast, more than 82% of the wild-type protein was associated with membranes. Wild-type p60src was phosphorylated by protein kinase C, a protein kinase which associates with membranes when activated. The mutant proteins were not. This finding supports the idea that within the intact cell the nonmyristylated p60src proteins are cytoplasmic and suggests that this apparent solubility is not an artifact of the cell fractionation procedure. The myristyl groups of p60src apparently encourages a tight association between protein and membranes and, by determining the cellular location of the enzyme, allows transformation to occur.

Published

1986

41. Activation of Nuclear RNA Polymerase by Sarkosyl

Author

Melvin H. Green, Janice E. Buss, and Patricio Gariglio

Subjects

chemistry.chemical_classification, RNase P, RNA-dependent RNA polymerase, RNA, RNA polymerase II, Endogeny, Biology, Biochemistry, Molecular biology, chemistry.chemical_compound, Enzyme, chemistry, RNA polymerase, biology.protein, Polymerase

Abstract

Treatment of mouse nuclei with the anionic detergent, sarkosyl, causes a several‐fold enhancement of endogenous RNA polymerase activity. The stimulatory effect of sarkosyl is due to two factors: a two‐fold increase in the initial activity of RNA polymerase II, and a prolongation of the total RNA polymerase reaction. Inhibition of RNase by sarkosyl could not account for either of these effects. Whereas sarkosyl and ammonium sulfate both stimulate RNA polymerase II, the effects are non‐additive, The RNA synthesized in the presence of sarkosyl sedimented primarily at 16‐23 S. whereas in the absence of detergent the RNA sedimented at 4–5 S. Sarkosyl caused the release of nearly all of the protein from cellular DNA, but apparently did not release initiated RNA polymerase. The stimulatory effect of sarkosyl on the initial rate of RNA synthesis catalyzed by RNA polymerase II can be explained by either of two extreme alternatives, or some combination of them. Either 50% of the enzyme is present in a totally repressed state, or all of the enzyme is partially inhibited by protein or other sarkosyl‐sensitive material. Copyright © 1975, Wiley Blackwell. All rights reserved

Published

1975

42. Rous sarcoma virus transforming protein lacking myristic acid phosphorylates known polypeptide substrates without inducing transformation

Author

Bartholomew M. Sefton, Janice E. Buss, and Mark P. Kamps

Subjects

animal structures, Muscle Proteins, Protein tyrosine phosphatase, Deoxyglucose, Myristic Acid, General Biochemistry, Genetics and Molecular Biology, SH3 domain, Structure-Activity Relationship, chemistry.chemical_compound, Animals, Phosphorylation, Tyrosine, Protein kinase A, Rous sarcoma virus, biology, Cell Cycle, Tyrosine phosphorylation, Oncogene Proteins, Viral, Protein-Tyrosine Kinases, Cell Transformation, Viral, Phosphoproteins, biology.organism_classification, Actins, Vinculin, Fibronectins, Avian Sarcoma Viruses, Phosphoglucomutase, chemistry, Biochemistry, Phosphopyruvate Hydratase, Chickens, Myristic Acids, Peptide Hydrolases, Proto-oncogene tyrosine-protein kinase Src

Abstract

Mutagenesis of glycine 2 of p60src, the transforming protein of Rous sarcoma virus (RSV), yields a protein that is neither myristylated nor bound to cellular membranes. Although these mutant viruses retain full tyrosine protein kinase activity, they are transformation-defective. We examined in detail tyrosine phosphorylation of cellular polypeptides and the phenotype induced by infection with two such viruses. Infection failed to cause growth in agar, cytoskeletal reorganization, or changes in fibronectin synthesis and protease secretion. Strikingly, tyrosine phosphorylation of the known substrates of p60src was extensive, and differed from that found in wild-type transformed cells only quantitatively. There was no apparent correlation between the extent to which any of eight known protein substrates of p60src were phosphorylated and the phenotype of infected cells. We suggest that the phosphorylation of as yet unidentified proteins, which are probably found in cellular membranes, is essential for transformation by RSV.

Published

1986

43. Activation of the Cellular Proto-Oncogene Product p21Ras by Addition of a Myristylation Signal

Author

James P. Schaeffer, Patricia A. Solski, Janice E. Buss, Marsha J. Macdonald, and Channing J. Der

Subjects

Retroviridae Proteins, Gene Products, gag, Myristic acid, In Vitro Techniques, Guanosine Diphosphate, Myristic Acid, Proto-Oncogene Mas, 3T3 cells, Proto-Oncogene Proteins p21(ras), Serine, Mice, chemistry.chemical_compound, Proto-Oncogene Proteins, medicine, Animals, Humans, Multidisciplinary, Oncogene, Chemistry, Cell Membrane, Cell Transformation, Neoplastic, Membrane, medicine.anatomical_structure, Mechanism of action, Biochemistry, Guanosine Triphosphate, medicine.symptom, Lipid modification, Myristic Acids, Protein Processing, Post-Translational, Cysteine

Abstract

The 21-kD proteins encoded by ras oncogenes (p21Ras) are modified covalently by a palmitate attached to a cysteine residue near the carboxyl terminus. Changing cysteine at position 186 to serine in oncogenic forms produces a nonpalmitylated protein that fails to associate with membranes and does not transform NIH 3T3 cells. Nonpalmitylated p21Ras derivatives were constructed that contained myristic acid at their amino termini to determine if a different form of lipid modification could restore either membrane association or transforming activity. An activated p21Ras, altered in this way, exhibited both efficient membrane association and full transforming activity. Surprisingly, myristylated forms of normal cellular Ras were also transforming. This demonstrates that Ras must bind to membranes in order to transmit a signal for transformation, but that either myristate or palmitate can perform this role. However, the normal function of cellular Ras is diverted to transformation by myristate and therefore must be regulated ordinarily by some unique property of palmitate that myristate does not mimic. Myristylation thus represents a novel mechanism by which Ras can become transforming.

Published

1989

44. Mutation of NH2-terminal glycine of p60src prevents both myristoylation and morphological transformation

Author

Janice E. Buss, Bartholomew M. Sefton, and Mark P. Kamps

Subjects

animal structures, Glycine, Myristic acid, Chick Embryo, Biology, Transfection, Myristic Acid, Oncogene Protein pp60(v-src), Viral Proteins, chemistry.chemical_compound, Animals, Protein myristoylation, Tyrosine, Myristoylation, Alanine, chemistry.chemical_classification, Multidisciplinary, Glycine cleavage system, Molecular biology, Amino acid, Cell Transformation, Neoplastic, Avian Sarcoma Viruses, chemistry, Biochemistry, Mutation, Saturated fatty acid, Myristic Acids, Protein Kinases, Research Article

Abstract

p60src, the transforming protein kinase of Rous sarcoma virus, contains the 14-carbon saturated fatty acid, myristic acid, linked through an amide bond to the alpha-amino group of its NH2-terminal glycine residue. Myristic acid is known to be attached to four other eukaryotic proteins. In each case the fatty acid is also linked through an amide bond to an NH2-terminal glycine. We have used oligonucleotide-directed mutagenesis to examine the amino acid specificity of the enzyme that myristoylates the NH2 terminus of these proteins. Replacement of the NH2-terminal glycine in p60src with either alanine or glutamic acid prevented myristoylation completely. This indicates that the myristoylating enzyme may have an absolute specificity for glycine. Strikingly, neither nonmyristoylated mutant src protein induced morphological transformation of infected cells, even though wild-type levels of phosphorylation of cellular proteins on tyrosine were observed in these cells. Since conversion of the NH2-terminal residue from glycine to alanine should have little effect on the conformation of p60src, the inability of this mutant p60src protein to induce morphological transformation suggests that the myristoyl moiety is essential for the transforming activity of the protein.

Published

1985

45. Myristic acid is attached to the transforming protein of Rous sarcoma virus during or immediately after synthesis and is present in both soluble and membrane-bound forms of the protein

Author

Mark P. Kamps, Janice E. Buss, and Bartholomew M. Sefton

Subjects

Cytoplasm, animal structures, Cell, Myristic acid, Chick Embryo, Myristic Acid, Oncogene Protein pp60(v-src), Viral Proteins, chemistry.chemical_compound, Polysome, medicine, Animals, Cycloheximide, Molecular Biology, Myristoylation, Rous sarcoma virus, biology, Cell Biology, biology.organism_classification, Cytosol, Membrane, medicine.anatomical_structure, Solubility, chemistry, Biochemistry, Electrophoresis, Polyacrylamide Gel, Myristic Acids, Research Article

Abstract

Myristic acid, a minor component of cellular fatty acids, has been shown previously to be covalently bound to most molecules of p60src, the transforming protein of Rous sarcoma virus. We have now determined at what time during the life cycle of p60src, and where within the cell, this lipid becomes attached to the protein. p60src was found to acquire myristic acid at only one time, during or immediately after its synthesis. p60src is known to be synthesized on free polysomes and appears at the cytoplasmic face of the plasma membrane after a lag of 10 min. The addition of myristic acid to p60src therefore precedes the binding of the protein to the plasma membrane. The lipid attached to p60src is a permanent, metabolically stable part of the protein; we found no evidence for turnover of the myristyl moiety. However, we did find myristate attached to various soluble forms of p60src and to a large number of cytosolic cellular proteins as well. This demonstrates that the attachment of myristic acid to a protein is not in itself sufficient to convert a soluble protein into a membrane-bound protein.

Published

1984

46. p21ras is modified by a farnesyl isoprenoid

Author

Channing J. Der, Patricia A. Solski, Patrick J. Casey, and Janice E. Buss

Subjects

G protein, Farnesyltransferase, Molecular Sequence Data, Mevalonic Acid, Oncogene Protein p21(ras), Transfection, Mice, Prenylation, Palmitoylation, Animals, Amino Acid Sequence, Peptide sequence, Cells, Cultured, chemistry.chemical_classification, Multidisciplinary, biology, organic chemicals, Farnesol, Amino acid, Genes, ras, Biochemistry, chemistry, biology.protein, Protein farnesylation, lipids (amino acids, peptides, and proteins), Research Article

Abstract

Association of oncogenic ras proteins with cellular membranes appears to be a crucial step in transformation, ras is synthesized as a cytosolic precursor, which is processed to a mature form that localizes to the plasma membrane. This processing involves, in part, a conserved sequence, Cys-Ali-Ali-Xaa (in which Ali is an amino acid with an aliphatic side chain and Xaa is any amino acid), at the COOH terminus of ras proteins. Yeast a-factor mating hormone precursor also possesses a COOH-terminal Cys-Ali-Ali-Xaa sequence. However, while the COOH-terminal cysteine has been implicated as a site of palmitoylation of ras proteins, in mature a-type mating factor this residue is modified by an isoprenoid, a farnesyl moiety. We asked whether the Cys-Ali-Ali-Xaa sequence signaled different modifications for the yeast peptides (farnesylation) than for ras proteins (palmitoylation) or whether ras proteins were similar to the mating factors and contained a previously undiscovered isoprenoid. We report here that the processing of ras proteins involves addition of a farnesyl moiety, apparently at the COOH-terminal cysteine analogous to the cysteine modified in the yeast peptides, and that farnesylation may be important for membrane association and transforming activity of ras proteins.

Published

1989

47. Characterization of the protein apparently responsible for the elevated tyrosine protein kinase activity in LSTRA cells

Author

T Patschinsky, A F Voronova, Bartholomew M. Sefton, Tony Hunter, and Janice E. Buss

Subjects

Protein tyrosine phosphatase, Mitogen-activated protein kinase kinase, Receptor tyrosine kinase, Cell Line, MAP2K7, Mice, chemistry.chemical_compound, Adenosine Triphosphate, Antigens, Neoplasm, Microsomes, Animals, Trypsin, Protein kinase A, Molecular Biology, Leukemia, Experimental, biology, Fatty Acids, Tyrosine phosphorylation, Cell Biology, Protein-Tyrosine Kinases, Phosphoproteins, Molecular biology, Neoplasm Proteins, Molecular Weight, chemistry, Biochemistry, biology.protein, Electrophoresis, Polyacrylamide Gel, Protein Kinases, Tyrosine kinase, Research Article, Proto-oncogene tyrosine-protein kinase Src

Abstract

The LSTRA murine thymoma cell line contains an elevated level of tyrosine protein kinase activity. When a microsomal preparation from these cells is incubated in vitro with ATP, the principal tyrosine protein kinase substrate is a 56,000-dalton protein, p56. We have found that an activity phosphorylating p56 on tyrosine can also be detected at low levels in microsomes from most, but not all, T lymphoma cell lines and from normal thymic tissue. Only 1 of 30 other lymphoma cell lines was found to contain an elevated level of such a tyrosine protein kinase. An activity that phosphorylated p56 in vitro was not detectable in the cells of other hematopoietic lineages. Anti-peptide antibodies reactive with the site of in vitro tyrosine phosphorylation of p56 allowed us to determine that the apparent abundance of the p56 polypeptide parallels closely the level of the tyrosine protein kinase activity in the cell lines examined. This suggests that p56 is the protein kinase responsible for the elevated tyrosine protein kinase activity in LSTRA cells and that the phosphorylation of p56 observed in vitro results from autophosphorylation. Two-dimensional tryptic peptide mapping revealed that p56 is distinct from the proteins encoded by the cellular genes which are the progenitors of retroviral tyrosine protein kinases, src, yes, fgr, abl, fes, and ros. Additionally, none of these proto-oncogenes was found to be transcribed at elevated levels in LSTRA or Thy19 cells. Like the catalytic subunit of the cyclic AMP-dependent protein kinase, the cellular and viral forms of p60src, and the protein phosphatase calcineurin B, p56 contains covalently bound fatty acid.

Published

1984

48. Protein kinase C phosphorylates pp60src at a novel site

Author

Kathleen L. Gould, Tony Hunter, James R. Woodgett, David Shalloway, Jonathan A. Cooper, and Janice E. Buss

Subjects

animal structures, Retroviridae Proteins, Mitogen-activated protein kinase kinase, Biology, General Biochemistry, Genetics and Molecular Biology, Oncogene Protein pp60(v-src), Substrate Specificity, MAP2K7, Mice, Serine, Animals, Amino Acid Sequence, c-Raf, Phosphorylation, Protein kinase A, Cells, Cultured, Protein Kinase C, Protein kinase C, Serine/threonine-specific protein kinase, MAP kinase kinase kinase, Muscles, Brain, Molecular biology, Rats, Kinetics, Avian Sarcoma Viruses, Biochemistry, Tetradecanoylphorbol Acetate, Rabbits, Protein Kinases, cGMP-dependent protein kinase

Abstract

The transforming protein of Rous sarcoma virus (pp60v-src) and its normal cellular homolog (pp60c-src) are demonstrated to be phosphorylated at serine 12 in vivo under certain conditions. We propose that protein kinase C is responsible for this modification based on the following evidence. First, the tumor promoters, 12-O-tetradecanoylphorbol-13-acetate and teleocidin, and synthetic diacylglycerol, known activators of protein kinase C in vivo, cause nearly complete phosphorylation of pp60src at serine 12. Second, among five purified serine/threonine-specific protein kinases tested, only protein kinase C phosphorylates pp60c-src and pp60v-src in vitro at serine 12. Third, purified protein kinase C phosphorylates a synthetic peptide corresponding to the N-terminal 20 amino acids of pp60c-src at serine 12. The physiological significance of this novel phosphorylation is discussed.

Published

1985

49. H-ras resides on clathrin-independent ARF6 vesicles that harbor little RAF-1, but not on clathrin-dependent endosomes

Author

Jodi McKay, Jian Ding, Xing Wang, Janice E. Buss, and Linda Ambrosio

Subjects

Endosome, media_common.quotation_subject, Endocytic cycle, Blotting, Western, Green Fluorescent Proteins, Protein trafficking, Vesicular Transport Proteins, Fluorescent Antibody Technique, Endosomal-recycling center, Endosomes, Endocytosis, Clathrin, Proto-Oncogene Proteins p21(ras), 03 medical and health sciences, Mice, Animals, Humans, Arf6, Internalization, Transport Vesicles, Molecular Biology, 030304 developmental biology, media_common, 0303 health sciences, biology, Effector, ADP-Ribosylation Factors, Vesicle, 030302 biochemistry & molecular biology, Cell Membrane, Cell Biology, Raf-1, Cell biology, Proto-Oncogene Proteins c-raf, ADP-Ribosylation Factor 6, biology.protein, NIH 3T3 Cells, Signal transduction, Signal Transduction, Ras

Abstract

Internalization of H-Ras from the cell surface onto endomembranes through vesicular endocytic pathways may play a significant role(s) in regulating the outcome of Ras signaling. However, the identity of Ras-associated subcellular vesicles and the means by which Ras localize to these internal sites remain elusive. In this study, we show that H-Ras is absent from endosomes initially derived from a clathrin-dependent endocytic pathway. Instead, both oncogenic H-Ras-61L and wild type H-Ras (basal or EGF-stimulated) bind Arf6-associated clathrin-independent endosomes and vesicles of the endosomal-recycling center (ERC). K-Ras4B-12V can also be internalized via Arf6 endosomes, and the C-terminal tails of both H-Ras and K-Ras4B are sufficient to mediate localization of GFP chimeras to Arf6-associated vesicles. Interestingly, little Raf-1 was found on these Arf6-associated endosomes even when active H-Ras was present. Instead, endogenous Raf-1 distributed primarily on EEA1-containing vesicles, suggesting that this H-Ras effector, although accessible for H-Ras interaction on the plasma membrane, appears to separate from its regulator during early stages of endocytosis. The discrete and dynamic distribution of Ras pathway components with spatio-temporal complexity may contribute to the specificity of Ras:effector interaction.

50. Farnesyl transferase inhibitors: the successes and surprises of a new class of potential cancer chemotherapeutics

Author

James C. Marsters and Janice E. Buss

Subjects

Pharmacology, Alkyl and Aryl Transferases, Farnesyl Transferase Inhibitor, Clinical Biochemistry, Cancer, Biological activity, Antineoplastic Agents, General Medicine, Neoplasms, Experimental, Biology, medicine.disease, Biochemistry, Rats, Genes, ras, Drug Discovery, Cancer research, medicine, Molecular Medicine, Animals, Enzyme Inhibitors, Molecular Biology

Abstract

Proteins that transmit abnormal growth signals offer enticing points of intervention for the treatment of cancer. The discovery that isoprenoid attachment is required for the aberrant biological activity of oncogenic Ras proteins has provided just such a target.