Your search keyword '"LiWei Tu"' showing total 19 results

1. Effect of Nascent Peptide Steric Bulk on Elongation Kinetics in the Ribosome Exit Tunnel

Author

Carol Deutsch, Ya-Ming Hou, Pengse Po, Lee C. Speight, Howard Gamper, Andrey Kosolapov, D. Miklos Szantai-Kis, LiWei Tu, E. James Petersson, and Erin Delaney

Subjects

0301 basic medicine, Steric effects, chemistry.chemical_classification, Peptidyl transferase, endocrine system diseases, biology, Stereochemistry, Chemistry, Peptide Chain Elongation, Translational, Proteolytic enzymes, Proteins, Peptide, Models, Biological, Ribosome, Article, Kinetics, 03 medical and health sciences, 030104 developmental biology, Structural Biology, Side chain, biology.protein, Peptide bond, Elongation, Ribosomes, Molecular Biology

Abstract

All proteins are synthesized by the ribosome, a macromolecular complex that accomplishes the life-sustaining tasks of faithfully decoding mRNA and catalyzing peptide bond formation at the peptidyl transferase center (PTC). The ribosome has evolved an exit tunnel to host the elongating new peptide, protect it from proteolytic digestion, and guide its emergence. It is here that the nascent chain begins to fold. This folding process depends on the rate of translation at the PTC. We report here that, besides PTC events, translation kinetics depend on steric constraints on nascent peptide side chains, and that confined movements of cramped side chains within and through the tunnel fine-tune elongation rates.

Published

2017

2. Determinants of Helix Formation for a Kv1.3 Transmembrane Segment inside the Ribosome Exit Tunnel

Author

LiWei Tu and Carol Deutsch

Subjects

Protein Conformation, alpha-Helical, 0301 basic medicine, Protein Folding, Kv1.3 Potassium Channel, Biology, Ribosome, Article, N-terminus, 03 medical and health sciences, Transmembrane domain, 030104 developmental biology, Biochemistry, Structural Biology, Biophysics, Protein folding, Ribosomes, Molecular Biology, Protein secondary structure, Peptide sequence, Alpha helix, Biogenesis

Abstract

Proteins begin to fold in the ribosome, and misfolding has pathological consequences. Among the earliest folding events in biogenesis is the formation of a helix, an elementary structure that is ubiquitously present and required for correct protein folding in all proteomes. The determinants underlying helix formation in the confined space of the ribosome exit tunnel are relatively unknown. We chose the second transmembrane segment, S2, of a voltage-gated potassium channel, Kv1.3, as a model to probe this issue. Since the N terminus of S2 is initially in an extended conformation in the folding vestibule of the ribosome yet ultimately emerges at the exit port as a helix, S2 is ideally suited for delineating sequential events and folding determinants of helix formation inside the ribosome. We show that S2's extended N terminus inside the tunnel is converted into a helix by a single, distant mutation in the nascent peptide. This transition depends on nascent peptide sequence at specific tunnel locations. Co-translational secondary folding of nascent chains inside the ribosome has profound physiological consequences that bear on correct membrane insertion, tertiary folding, oligomerization, and biochemical modification of the newborn protein during biogenesis.

Published

2017

3. Determinants of pore folding in potassium channel biogenesis

Author

Erin Delaney, Pooja Khanna, Carol Deutsch, LiWei Tu, and John M. Robinson

Subjects

Models, Molecular, Membrane potential, Potassium Channels, Multidisciplinary, Sequence Homology, Amino Acid, Molecular Sequence Data, Biological Sciences, Biology, Permeation, Potassium channel, Protein Structure, Tertiary, chemistry.chemical_compound, Monomer, Biochemistry, chemistry, Biophysics, Animals, Humans, Electrophoresis, Polyacrylamide Gel, Amino Acid Sequence, Peptide sequence, Ion channel, Biogenesis

Abstract

Many ion channels, both selective and nonselective, have reentrant pore loops that contribute to the architecture of the permeation pathway. It is a fundamental feature of these diverse channels, regardless of whether they are gated by changes of membrane potential or by neurotransmitters, and is critical to function of the channel. Misfolding of the pore loop leads to loss of trafficking and expression of these channels on the cell surface. Mature tetrameric potassium channels contain an α-helix within the pore loop. We systematically mutated the "pore helix" residues of the channel Kv1.3 and assessed the ability of the monomer to fold into a tertiary reentrant loop. Our results show that pore loop residues form a canonical α-helix in the monomer early in biogenesis and that disruption of tertiary folding is caused by hydrophilic substitutions only along one face of this α-helix. These results provide insight into the determinants of the reentrant pore conformation, which is essential for ion channel function.

Published

2014

4. Arginine Changes the Conformation of the Arginine Attenuator Peptide Relative to the Ribosome Tunnel

Author

Arthur E. Johnson, Jiajie Wei, Matthew S. Sachs, LiWei Tu, Cheng Wu, Carol Deutsch, and Pen Jen Lin

Subjects

Ribosomal Proteins, Arginine, Protein Conformation, Molecular Sequence Data, Peptide, Biology, Ribosome, Article, Fungal Proteins, Open Reading Frames, Protein structure, Structural Biology, Ribosomal protein, Translational regulation, Amino Acid Sequence, Molecular Biology, Peptide sequence, chemistry.chemical_classification, Fungal protein, Base Sequence, Peptide Fragments, Neurospora, chemistry, Biochemistry, Mutation, Carbon-Nitrogen Ligases with Glutamine as Amide-N-Donor, Ribosomes

Abstract

The fungal arginine attenuator peptide (AAP) is a regulatory peptide that controls ribosome function. As a nascent peptide within the ribosome exit tunnel, it acts to stall ribosomes in response to arginine (Arg). We used three approaches to probe the molecular basis for stalling. First, PEGylation assays revealed that the AAP did not undergo overall compaction in the tunnel in response to Arg. Second, site-specific photocross-linking showed that Arg altered the conformation of the wild-type AAP, but not of nonfunctional mutants, with respect to the tunnel. Third, using time-resolved spectral measurements with a fluorescent probe placed in the nascent AAP, we detected sequence-specific changes in the disposition of the AAP near the peptidyltransferase center in response to Arg. These data provide evidence that an Arg-induced change in AAP conformation and/or environment in the ribosome tunnel is important for stalling.

Published

2012

5. Biogenesis of the T1-S1 linker of voltage-gated [K.sup.+] channels

Author

LiWei Tu, Deutsch, Carol, and Jing Wang

Subjects

Membrane proteins -- Structure, Life -- Origin, Biological sciences, Chemistry

Abstract

The biogenesis of secondary structure of three distinct regions of Kv1.3, a highly homologous isoform of a six-transmembrane voltage-gated potassium channel, such as the [alpha]5 helix of the T1 domain, the T1-S1 linker and the S1 transmembrane segment, are reported. The results have shown that the [alpha]5 helix forms compact secondary structure, the T1-S1 linker does not form a compact structure and S1 compacts only when it is positioned in the last 20 Angstrom of the tunnel.

Published

2007

6. A Folding Zone in the Ribosomal Exit Tunnel for Kv1.3 Helix Formation

Author

Carol Deutsch and LiWei Tu

Subjects

Models, Molecular, Protein Folding, Molecular Sequence Data, Peptide Chain Elongation, Translational, In Vitro Techniques, Biology, Ribosome, Protein Structure, Secondary, Article, Structural Biology, Humans, Amino Acid Sequence, Molecular Biology, Protein secondary structure, Kv1.3 Potassium Channel, Ribosomal RNA, Translocon, Recombinant Proteins, Transmembrane protein, Amino Acid Substitution, Biochemistry, Helix, Mutagenesis, Site-Directed, Biophysics, Protein folding, Ribosomes, Linker

Abstract

Although it is now clear that protein secondary structure can be acquired early, while the nascent peptide resides within the ribosomal exit tunnel, the principles governing folding of native polytopic proteins have not yet been elucidated. We now report an extensive investigation of native Kv1.3, a voltage-gated K + channel, including transmembrane and linker segments synthesized in sequence. These native segments form helices vectorially (N- to C-terminus) only in a permissive vestibule located in the last 20 A of the tunnel. Native linker sequences similarly fold in this vestibule. Finally, secondary structure acquired in the ribosome is retained in the translocon. These findings emerge from accessibility studies of a diversity of native transmembrane and linker sequences and may therefore be applicable to protein biogenesis in general.

Published

2010

7. The dipeptidyl-aminopeptidase-like protein 6 is an integral voltage sensor-interacting β-subunit of neuronal KV4.2 channels

Author

Kevin Dougherty, LiWei Tu, Manuel Covarrubias, and Carol Deutsch

Subjects

Potassium Channels, Biophysics, Nerve Tissue Proteins, Nanotechnology, Gating, Biochemistry, Voltage sensor, Animals, Humans, Dipeptidyl-Peptidases and Tripeptidyl-Peptidases, Dipeptidyl aminopeptidase-like protein 6, Neurons, Kv1.3 Potassium Channel, Voltage-gated ion channel, Chemistry, Translation (biology), Protein Biochemistry, Electrophysiology, Protein Subunits, Transmembrane domain, Shal Potassium Channels, Ion Channel Gating, Peptide Hydrolases, Protein Binding, Communication channel

Abstract

Auxiliary beta-subunits dictate the physiological properties of voltage-gated K(+) (K(V)) channels in excitable tissues. In many instances, however, the underlying mechanisms of action are poorly understood. The dipeptidyl-aminopeptidase-like protein 6 (DPP6) is a specific beta-subunit of neuronal K(V)4 channels, which may promote gating through interactions between the single transmembrane segment of DPP6 and the channel's voltage sensing domain (VSD). A combination of gating current measurements and protein biochemistry (in-vitro translation and co-immunoprecipitations) revealed preferential physical interaction between the isolated K(V)4.2-VSD and DPP6. Significantly weaker interactions were detected between DPP6 and K(V)1.3 channels or the K(V)4.2 pore domain. More efficient gating charge movement resulting from a direct interaction between DPP6 and the K(V)4.2-VSD is unique among the known actions of K(V) channel beta-subunits. This study shows that the modular VSD of a K(V) channel can be directly regulated by transmembrane protein-protein interactions involving an extrinsic beta-subunit. Understanding these interactions may shed light on the pathophysiology of recently identified human disorders associated with mutations affecting the dpp6 gene.

Published

2009

8. Association between IFN-α and primary Sjogren's syndrome

Author

Chuangqi Yu, Lai-ping Zhong, Zhiyuan Zhang, Lingyan Zheng, Liwei Tu, and Chi Yang

Subjects

Adult, Male, medicine.medical_specialty, Pathology, Gene Expression, Salivary Glands, Minor, Polymerase Chain Reaction, law.invention, stomatognathic system, Downregulation and upregulation, law, Internal medicine, Biopsy, Gene expression, medicine, Humans, General Dentistry, Polymerase chain reaction, Aged, medicine.diagnostic_test, business.industry, Case-control study, Interferon-alpha, Middle Aged, Immunohistochemistry, Lip, Up-Regulation, stomatognathic diseases, Exact test, Sjogren's Syndrome, Endocrinology, Otorhinolaryngology, Case-Control Studies, Female, Surgery, Oral Surgery, Sjogren s, business

Abstract

Objective To determine the level of IFN-α in labial salivary glands, plasma, and peripheral blood cells from patients with primary Sjogren's syndrome (pSS). Methods Labial salivary gland biopsy specimens, plasma, and peripheral blood cells from patients with pSS were investigated. The IFN-α–positive cells, measurable IFN-α level, and IFN-α gene mRNA level were determined by using immunohistochemistry, ELISA, and real-time PCR, respectively. Statistical analysis was performed by Student t test or Fisher's exact test. Results About 60% of patients (22/37) with pSS had significantly higher scores of IFN-α–positive cells in labial gland biopsy and most IFN-α–positive cells were localized predominantly in the lymphocytes and ductal epithelial cells. But in 3 of the control samples (3/24), the IFN-α–positive cells existed only in the ductal epithelial cells with lower scores. Forty-three percents of the patients with pSS were found with detectable IFN-α concentration in plasma (≥12.5 pg/mL), and their concentration was higher than that of control group. Furthermore, the IFN-α mRNA levels in peripheral blood cells were up-regulated in the patients with pSS. Conclusion No matter in labial salivary glands or hematoplasma, or peripheral blood cells, IFN-α expression levels are up-regulated in patients with primary Sjogren's syndrome.

Published

2009

9. Biogenesis of the T1−S1 Linker of Voltage-Gated K+ Channels

Author

Jing Wang, Carol Deutsch, and LiWei Tu

Subjects

Models, Molecular, chemistry.chemical_classification, Gene isoform, Potassium Channels, Molecular Sequence Data, Peptide, Crystal structure, Biochemistry, Protein Structure, Secondary, Potassium channel, Transmembrane domain, Crystallography, Biopolymers, chemistry, Electrophoresis, Polyacrylamide Gel, Amino Acid Sequence, Ion Channel Gating, Linker, Protein secondary structure, Biogenesis

Abstract

In the model derived from the crystal structure of Kv1.2, a six-transmembrane voltage-gated potassium channel, the linker between a cytosolic tetramerization domain, T1, and the first transmembrane segment, S1, is projected radially outward from the channel's central axis. This T1-S1 linker was modeled as two polyglycine helices to accommodate the residues between T1 and S1 [Long et al. (2005) Science 309, 897-903]; however, the structure of this linker is not known. Here, we investigate whether a compact secondary structure of the T1-S1 linker exists at an early stage of Kv channel biogenesis. We have used a mass-tagging accessibility assay to report the biogenesis of secondary structure for three consecutive regions of Kv1.3, a highly homologous isoform of Kv1.2. The three regions include the T1-S1 linker and its two flanking regions, alpha5 of the T1 domain and S1. Both alpha5 and S1 manifest compact structures (helical) inside the ribosomal exit tunnel, whereas the T1-S1 linker does not. Moreover, the location of the peptide in the tunnel influences compaction.

Published

2007

10. Structure Acquisition of the T1 Domain of Kv1.3 during Biogenesis

Author

Carol Deutsch, Andrey Kosolapov, Jing Wang, and LiWei Tu

Subjects

Protein Folding, Kv1.3 Potassium Channel, Neuroscience(all), General Neuroscience, Molecular Sequence Data, Sequence Homology, Biology, Ribosomal RNA, Translocon, Bioinformatics, Ribosome, Protein Structure, Secondary, Protein tertiary structure, Protein Structure, Tertiary, Folding (chemistry), Protein Subunits, Potassium Channels, Voltage-Gated, Biophysics, Animals, Protein folding, Amino Acid Sequence, Protein Processing, Post-Translational, Ribosomes, Biogenesis, Ion channel

Abstract

The T1 recognition domains of voltage-gated K + (Kv) channel subunits form tetramers and acquire tertiary structure while still attached to their individual ribosomes. Here we ask when and in which compartment secondary and tertiary structures are acquired. We answer this question using biogenic intermediates and recently developed folding and accessibility assays to evaluate the status of the nascent Kv peptide both inside and outside of the ribosome. A compact structure (likely helical) that corresponds to a region of helicity in the mature structure is already manifest in the nascent protein within the ribosomal tunnel. The T1 domain acquires tertiary structure only after emerging from the ribosomal exit tunnel and complete synthesis of the T1-S1 linker. These measurements of ion channel folding within the ribosomal tunnel and its exit port bear on basic principles of protein folding and pave the way for understanding the molecular basis of protein misfolding, a fundamental cause of channelopathies.

Published

2004

11. Transmembrane Segments Form Tertiary Hairpins in the Folding Vestibule of the Ribosome

Author

LiWei Tu, Carol Deutsch, and Pooja Khanna

Subjects

Protein Folding, Kv1.3 Potassium Channel, Chemistry, Protein Conformation, Molecular Sequence Data, Ribosome, Transmembrane protein, Article, Folding (chemistry), Crystallography, Protein structure, Membrane protein, Structural Biology, Vestibule, Biophysics, Protein folding, Amino Acid Sequence, Molecular Biology, Peptide sequence, Ribosomes

Abstract

Folding of membrane proteins begins in the ribosome as the peptide is elongated. During this process, the nascent peptide navigates along 100 A of tunnel from the peptidyltransferase center to the exit port. Proximal to the exit port is a “folding vestibule” that permits the nascent peptide to compact and explore conformational space for potential tertiary folding partners. The latter occurs for cytosolic subdomains but has not yet been shown for transmembrane segments. We now demonstrate, using an accessibility assay and an improved intramolecular crosslinking assay, that the helical transmembrane S3b–S4 hairpin (“paddle”) of a voltage-gated potassium (Kv) channel, a critical region of the Kv voltage sensor, forms in the vestibule. S3–S4 hairpin interactions are detected at an early stage of Kv biogenesis. Moreover, this vestibule hairpin is consistent with a closed-state conformation of the Kv channel in the plasma membrane.

Published

2013

12. Truncated K+ channel DNA sequences specifically suppress lymphocyte K+ channel gene expression

Author

Carol Deutsch, V. Santarelli, and LiWei Tu

Subjects

Potassium Channels, Mutant, Xenopus, Biophysics, Gene Expression, In Vitro Techniques, Biology, Transfection, Jurkat cells, complex mixtures, Biophysical Phenomena, Cell Line, RNA, Complementary, Mice, Xenopus laevis, Suppression, Genetic, Plasmid, Animals, Humans, Cytotoxic T cell, Lymphocytes, Sequence Deletion, chemistry.chemical_classification, Kv1.3 Potassium Channel, Voltage-gated ion channel, urogenital system, DNA, biology.organism_classification, Molecular biology, Amino acid, Electrophysiology, chemistry, Potassium Channels, Voltage-Gated, Oocytes, Female, biological phenomena, cell phenomena, and immunity, Research Article

Abstract

We have constructed a series of deletion mutants of Kv1.3, a Shaker-like, voltage-gated K+ channel, and examined the ability of these truncated mutants to form channels and to specifically suppress full-length Kv1.3 currents. These constructs were expressed heterologously in both Xenopus oocytes and a mouse cytotoxic T cell line. Our results show that a truncated mutant Kv1.3 must contain both the amino terminus and the first transmembrane-spanning segment, S1, to suppress full-length Kv1.3 currents. Amino-terminal-truncated DNA sequences from one subfamily suppress K+ channel expression of members of only the same subfamily. The first 141 amino acids of the amino-terminal of Kv1.3 are not necessary for channel formation. Deletion of these amino acids yields a current identical to that of full-length Kv1.3, except that it cannot be suppressed by a truncated Kv1.3 containing the amino terminus and S1. To test the ability of truncated Kv1.3 to suppress endogenous K+ currents, we constructed a plasmid that contained both truncated Kv1.3 and a selection marker gene (mouse CD4). Although constitutively expressed K+ currents in Jurkat (a human T cell leukemia line) and GH3 (an anterior pituitary cell line) cells cannot be suppressed by this double-gene plasmid, stimulated (up-regulated) Shaker-like K+ currents in GH3 cells can be suppressed.

Published

1995

13. Transmembrane biogenesis of Kv1.3

Author

William R. Skach, Andrew Helm, Carol Deutsch, Jing Wang, and LiWei Tu

Subjects

Signal peptide, Glycosylation, Potassium Channels, Transcription, Genetic, medicine.medical_treatment, Molecular Sequence Data, Chromosomal translocation, Biology, Cleavage (embryo), Endoplasmic Reticulum, Biochemistry, chemistry.chemical_compound, Xenopus laevis, medicine, Animals, Amino Acid Sequence, Protease, Kv1.3 Potassium Channel, Endoplasmic reticulum, Intracellular Membranes, Transmembrane protein, Peptide Fragments, Cell biology, chemistry, Potassium Channels, Voltage-Gated, Protein Biosynthesis, Shaker Superfamily of Potassium Channels, Cattle, Rabbits, Endopeptidase K, Biogenesis

Abstract

Using a combination of protease protection, glycosylation, and carbonate extraction assays, we have characterized the topogenic determinants encoded by Kv1.3 segments that mediate translocation events during endoplasmic reticulum (ER) biogenesis. Transmembrane segments S1, S2, S3, S5, and S6 initiate translocation, only S1 and S2 strongly (60%) anchor themselves in the membrane, S5 exhibits signal anchor activity and contains a cryptic cleavage site, and S3 and S6 fail to integrate into the membrane. Elongation of each single-transmembrane construct to include multiple transmembrane segments alters integration and translocation efficiencies, indicating that multiple topogenic determinants cooperate during Kv1. 3 topogenesis and assembly. Several surprising findings emerged from these studies. First, in the presence of T1, the N-terminal recognition domain, S1 was unable to initiate either translocation or membrane integration. As a result, S2 likely functions as the initial signal sequence to establish Kv1.3 N-terminus topology. Second, S4 independently integrates into the membrane. Third, S6 plus the C-terminus of Kv1.3 is a secretory protein but can be converted to a membrane-integrated protein with a correctly oriented, cytosolic C-terminus by linking S6 to S5 and the pore loop. These results have implications for the role of the N-terminus in Kv biogenesis and on the mechanisms of dominant negative suppression of Kv1.3 by truncated Kv1.3 fragments [Tu et al. (1996) J. Biol. Chem. 271, 18904-18911].

Published

2000

14. Voltage-gated K+ channels contain multiple intersubunit association sites

Author

William R. Skach, LiWei Tu, Vincent P. Santarelli, Zu Fang Sheng, Carol Deutsch, and Debkumar Pain

Subjects

Gene isoform, Subfamily, Potassium Channels, Immunoprecipitation, Xenopus, Peptide, In Vitro Techniques, Biochemistry, RNA, Complementary, Xenopus laevis, Animals, Molecular Biology, Sequence Deletion, chemistry.chemical_classification, Binding Sites, Kv1.3 Potassium Channel, biology, Molecular Structure, Translation (biology), Cell Biology, biology.organism_classification, Molecular biology, Transmembrane protein, Peptide Fragments, Amino acid, Cell biology, chemistry, Potassium Channels, Voltage-Gated, Protein Biosynthesis, Oocytes, Female, Ion Channel Gating

Abstract

A domain in the cytoplasmic NH2 terminus of voltage-gated K+ channels supervises the proper assembly of specific tetrameric channels (Li, M., Jan, J. M., and Jan, L. Y.(1992) Science 257, 1225-1230; Shen, N. V., Chen X., Boyer, M. M., and Pfaffinger, P. (1993) Neuron 11, 67-76). It is referred to as a first tetramerization domain, or T1 (Shen, N. V., Chen X., Boyer, M. M., and Pfaffinger, P.(1993) Neuron 11, 67-76). However, a deletion mutant of Kv1.3 that lacks the first 141 amino acids, Kv1.3 (T1(-)) forms functional channels, suggesting that additional association sites in the central core of Kv1.3 mediate oligomerization. To characterize these sites, we have tested the abilities of cRNA Kv1.3 (T1(-)) fragments co-injected with Kv1.3 (T1(-)) to suppress current in Xenopus oocytes. The fragments include portions of the six putative transmembrane segments, S1 through S6, specifically: S1, S1-S2, S1-S2-S3, S2-S3, S2-S3-S4, S3-S4, S3-S4-S5, S2 through COOH, S3 through COOH, S4 through COOH, and S5-S6-COOH. Electrophysiologic experiments show that the fragments S1-S2-S3, S3-S4-S5, S2 through COOH, and S3 through COOH strongly suppress Kv1.3 (T1(-)) current, while others do not. Suppression of expressed current is due to specific effects of the translated peptide Kv1.3 fragments, as validated by in vivo immunoprecipitation studies of a strong suppressor and a nonsuppressor. Pulse-chase experiments indicate that translation of truncated peptide fragments neither prevents translation of Kv1.3 (T1(-)) nor increases its rate of degradation. Co-immunoprecipitation experiments suggest that suppression involves direct association of a peptide fragment with Kv1.3 (T1(-)). Fragments that strongly suppress Kv1.3 (T1(-)) also suppress an analogous NH2-terminal deletion mutant of Kv2.1 (Kv2.1 (DeltaN139)), an isoform belonging to a different subfamily. Our results indicate that sites in the central core of Kv1.3 facilitate intersubunit association and that there are suppression sites in the central core, which are promiscuous across voltage-gated K+ channel subfamilies.

Published

1996

15. A Universal Zone in the Ribosomal Exit Tunnel for Helix Formation in Kv1.3

Author

LiWei Tu and Carol Deutsch

Subjects

Folding (chemistry), Transmembrane domain, Crystallography, Chemistry, Helix, Biophysics, Translocon, Linker, Protein secondary structure, Transmembrane protein, Biogenesis

Abstract

Crystal structures of Kv channels have given us a reasonably complete view of the structure of a mature Kv channel. However, details of its structure acquisition are missing. We now report on the biogenesis of secondary structure of the transmembrane segments and intervening linkers of Kv1.3. Using a combination of accessibility assays, both cysteine pegylation (Tu et al., 2007; Lu and Deutsch, 2005) and N-linked glycosylation (Mingarro et al., 2000), we derive the following principles of folding for nascent sequences within their native contexts. First, native helical transmembrane sequences initially form helices only within the distal 20A of the ribosomal tunnel near the exit port. We refer to this region as the α-zone. Helix formation in transmembrane segments thus occurs vectorially from N- to C-terminus as each segment moves sequentially into the α-zone. Second, linker sequences also form compact structures inside the α-zone even in the absence of helix formation of their C-terminal flanking transmembrane segments. Third, helical structures, whether transmembrane or linker segments, formed in the tunnel retain their helicity in the translocon. These principles emerge from a diversity of native transmembrane and linker sequences that comprise Kv1.3 and may therefore be applicable to protein biogenesis in general.[Supported by NIH grant GM 52302].References: Tu et al., Biochemistry 46: 8075, 2007; Lu and Deutsch, Biochemistry 44: 8230, 2005; Mingarro et al., BMC Cell Biol. 1: 3, 2000.

Published

2010

16. Determinants of pore folding in potassium channel biogenesis.

Author

Delaney, Erin, Khanna, Pooja, LiWei Tu, Robinson, John M., and Deutsch, Carol

Subjects

POTASSIUM channels, ION channels, NEUROTRANSMITTERS, CELL membranes, MONOMERS

Abstract

Many ion channels, both selective and nonselective, have reentrant pore loops that contribute to the architecture of the permeation pathway. It is a fundamental feature of these diverse channels, regardless of whether they are gated by changes of membrane potential or by neurotransmitters, and is critical to function of the channel. Misfolding of the pore loop leads to loss of trafficking and expression of these channels on the cell surface. Mature tetrameric potassium channels contain an α-helix within the pore loop. We systematically mutated the "pore helix" residues of the channel Kv1.3 and assessed the ability of the monomer to fold into a tertiary reentrant loop. Our results show that pore loop residues form a canonical α-helix in the monomer early in biogenesis and that disruption of tertiary folding is caused by hydrophilic substitutions only along one face of this α-helix. These results provide insight into the determinants of the reentrant pore conformation, which is essential for ion channel function. [ABSTRACT FROM AUTHOR]

Published

2014

17. Biogenesis of the T1-S1 Linker of Voltage-Gated K+ Channels.

Author

LiWei Tu, Jing Wang, and Deutsch, Carol

Subjects

*ORIGIN of life, *POTASSIUM channels, *TRANSFERASES, *POLYETHYLENE glycol, *IMIDES, *PEPTIDES, *GLYCINE

Abstract

In the model derived from the crystal structure of Kv1.2, a six-transmembrane voltage-gated potassium channel, the linker between a cytosolic tetramerization domain, T1, and the first transmembrane segment, S1, is projected radially outward from the channel's central axis. This T1—S1 linker was modeled as two polyglycine helices to accommodate the residues between T1 and S1 [Long et al. (2005) Science 309, 897–9031; however, the structure of this linker is not known. Here, we investigate whether a compact secondary structure of the T1—S1 linker exists at an early stage of Kv channel biogenesis. We have used a mass-tagging accessibility assay to report the biogenesis of secondary structure for three consecutive regions of Kv1.3, a highly homologous isoform of Kv1.2. The three regions include the T1—S1 linker and its two flanking regions, α5 of the T1 domain and S1. Both α5 and S1 manifest compact structures (helical) inside the ribosomal exit tunnel, whereas the T1—S1 linker does not. Moreover, the location of the peptide in the tunnel influences compaction. [ABSTRACT FROM AUTHOR]

Published

2007

18. Transmembrane biogenesis of Kv1.3.

Author

LiWei Tu and Jing Wang

Subjects

*ENDOPLASMIC reticulum, *GLYCOSYLATION

Abstract

Studies the mechanisms by which a Shaker-like voltage-gated K+ (Kv) channel called Kv 1.3 achieves its final topology in the endoplasmic reticulum membrane. Use of a combination of protease protection, glycosylation and carbonate extraction assays; Use of transmembrane segments; Elongation of single-transmembrane constructs.

Published

2000

19. Evidence for Dimerization of Dimers in K+ Channel Assembly

Author

Carol Deutsch and LiWei Tu

Subjects

Potassium Channels, Stereochemistry, Protein Conformation, Kinetics, Mutant, Biophysics, In Vitro Techniques, Models, Biological, Biophysical Phenomena, law.invention, Membrane Potentials, chemistry.chemical_compound, Xenopus laevis, Protein structure, law, Animals, Binding site, Gel electrophoresis, Binding Sites, Neuropeptides, Potassium channel, Recombinant Proteins, Monomer, Biochemistry, chemistry, Shaw Potassium Channels, Potassium Channels, Voltage-Gated, Mutation, Recombinant DNA, Oocytes, Female, Dimerization, Research Article

Abstract

Voltage-gated K+ channels are tetrameric, but how the four subunits assemble is not known. We analyzed inactivation kinetics and peak current levels elicited for a variety of wild-type and mutant Kv1.3 subunits, expressed singly, in combination, and as tandem constructs, to show that 1) the dominant pathway involves a dimerization of dimers, and 2) dimer-dimer interaction may involve interaction sites that differ from those involved in monomer-monomer association. Moreover, using nondenaturing gel electrophoresis, we detected dimers and tetramers, but not trimers, in the translation reaction of Kv1.3 monomers.