Your search keyword '"Zvia Konrad"' showing total 21 results

1. Tomato ABSCISIC ACID STRESS RIPENING (ASR) gene family revisited.

Author

Ido Golan, Pia Guadalupe Dominguez, Zvia Konrad, Doron Shkolnik-Inbar, Fernando Carrari, and Dudy Bar-Zvi

Subjects

Medicine, Science

Abstract

Tomato ABSCISIC ACID RIPENING 1 (ASR1) was the first cloned plant ASR gene. ASR orthologs were then cloned from a large number of monocot, dicot and gymnosperm plants, where they are mostly involved in response to abiotic (drought and salinity) stress and fruit ripening. The tomato genome encodes five ASR genes: ASR1, 2, 3 and 5 encode low-molecular-weight proteins (ca. 110 amino acid residues each), whereas ASR4 encodes a 297-residue polypeptide. Information on the expression of the tomato ASR gene family is scarce. We used quantitative RT-PCR to assay the expression of this gene family in plant development and in response to salt and osmotic stresses. ASR1 and ASR4 were the main expressed genes in all tested organs and conditions, whereas ASR2 and ASR3/5 expression was two to three orders of magnitude lower (with the exception of cotyledons). ASR1 is expressed in all plant tissues tested whereas ASR4 expression is limited to photosynthetic organs and stamens. Essentially, ASR1 accounted for most of ASR gene expression in roots, stems and fruits at all developmental stages, whereas ASR4 was the major gene expressed in cotyledons and young and fully developed leaves. Both ASR1 and ASR4 were expressed in flower organs, with ASR1 expression dominating in stamens and pistils, ASR4 in sepals and petals. Steady-state levels of ASR1 and ASR4 were upregulated in plant vegetative organs following exposure to salt stress, osmotic stress or the plant abiotic stress hormone abscisic acid (ABA). Tomato plants overexpressing ASR1 displayed enhanced survival rates under conditions of water stress, whereas ASR1-antisense plants displayed marginal hypersensitivity to water withholding.

Published

2014

2. Additional file 1: Table S1. of The Arabidopsis paralogs, PUB46 and PUB48, encoding U-box E3 ubiquitin ligases, are essential for plant response to drought stress

Author

Adler, Guy, Zvia Konrad, Lyad Zamir, Mishra, Amit, Raveh, Dina, and Dudy Bar-Zvi

Abstract

List of primers used in this study. (DOCX 18 kb)

Published

2017

3. Add salt, add sugar: N-glycosylation in Haloferax volcanii

Author

Zvia Konrad, Shai Naparstek, Jerry Eichler, Lina Kaminski, Chen Cohen-Rosenzweig, Adi Arbiv, and Lina Kandiba

Subjects

chemistry.chemical_classification, Glycosylation, Archaeal Proteins, Haloferax volcanii, Sodium Chloride, Biology, biology.organism_classification, Biochemistry, Mass Spectrometry, carbohydrates (lipids), chemistry.chemical_compound, chemistry, N-linked glycosylation, Carbohydrate Metabolism, Glycoprotein, Protein Processing, Post-Translational, Function (biology)

Abstract

Although performed by members of all three domains of life, the archaeal version of N-glycosylation remains the least understood. Studies on Haloferax volcanii have, however, begun to correct this situation. A combination of bioinformatics, molecular biology, biochemical and mass spectrometry approaches have served to delineate the Agl pathway responsible for N-glycosylation of the S-layer glycoprotein, a reporter of this post-translational modification in Hfx. volcanii. More recently, differential N-glycosylation of the S-layer glycoprotein as a function of environmental salinity was demonstrated, showing that this post-translational modification serves an adaptive role in Hfx. volcanii. Furthermore, manipulation of the Agl pathway, together with the capability of Hfx. volcanii to N-glycosylate non-native proteins, forms the basis for establishing this species as a glyco-engineering platform. In the present review, these and other recent findings are addressed.

Published

2013

4. The Arabidopsis paralogs, PUB46 and PUB48, encoding U-box E3 ubiquitin ligases, are essential for plant response to drought stress

Author

Dina Raveh, Dudy Bar-Zvi, Guy Adler, Zvia Konrad, Amit Kumar Mishra, and Lyad Zamir

Subjects

0106 biological sciences, 0301 basic medicine, Ubiquitin-Protein Ligases, Arabidopsis, Plant Science, Biology, Protein degradation, 01 natural sciences, Chromosomes, Plant, 03 medical and health sciences, Ubiquitin, Gene Expression Regulation, Plant, Stress, Physiological, Botany, Gene, Regulation of gene expression, Abiotic stress, Arabidopsis Proteins, Research, biology.organism_classification, Cell biology, Droughts, 030104 developmental biology, Proteasome, Mutation, biology.protein, 010606 plant biology & botany

Abstract

Background Plants respond to abiotic stress on physiological, biochemical and molecular levels. This includes a global change in their cellular proteome achieved by changes in the pattern of their protein synthesis and degradation. The ubiquitin-proteasome system (UPS) is a key player in protein degradation in eukaryotes. Proteins are marked for degradation by the proteasome by coupling short chains of ubiquitin polypeptides in a three-step pathway. The last and regulatory stage is catalyzed by a member of a large family of substrate-specific ubiquitin ligases. Results We have identified AtPUB46 and AtPUB48—two paralogous genes that encode ubiquitin ligases (E3s)—to have a role in the plant environmental response. The AtPUB46, −47, and −48 appear as tandem gene copies on chromosome 5, and we present a phylogenetic analysis that traces their evolution from an ancestral PUB-ARM gene. Single homozygous T-DNA insertion mutants of AtPUB46 and AtPUB48 displayed hypersensitivity to water stress; this was not observed for similar mutants of AtPUB47. Although the three genes show a similar spatial expression pattern, the steady state levels of their transcripts are differentially affected by abiotic stresses and plant hormones. Conclusions AtPUB46 and AtPUB48 encode plant U-Box E3s and are involved in the response to water stress. Our data suggest that despite encoding highly homologous proteins, AtPUB46 and AtPUB48 biological activity does not fully overlap. Electronic supplementary material The online version of this article (doi:10.1186/s12870-016-0963-5) contains supplementary material, which is available to authorized users.

Published

2016

5. AglR is required for addition of the final mannose residue of the N-linked glycan decorating the Haloferax volcanii S-layer glycoprotein

Author

Jerry Eichler, Ziqiang Guan, Zvia Konrad, Mehtap Abu-Qarn, and Lina Kaminski

Subjects

Spectrometry, Mass, Electrospray Ionization, Glycosylation, Archaeal Proteins, Biophysics, Mannose, N linked glycans, Biology, Biochemistry, Article, Residue (chemistry), chemistry.chemical_compound, N-linked glycosylation, Polysaccharides, Tandem Mass Spectrometry, Amino Acid Sequence, Haloferax volcanii, Molecular Biology, chemistry.chemical_classification, Membrane Glycoproteins, Organisms, Genetically Modified, biology.organism_classification, chemistry, Glycoprotein, Protein Processing, Post-Translational, S-layer, Chromatography, Liquid, Archaea

Abstract

Recent studies of Haloferax volcanii have begun to elucidate the steps of N-glycosylation in Archaea, where this universal post-translational modification remains poorly described. In Hfx. volcanii, a series of Agl proteins catalyzes the assembly and attachment of a N-linked pentasaccharide to the S-layer glycoprotein. Although roles have been assigned to the majority of Agl proteins, others await description. In the following, the contribution of AglR to N-glycosylation was addressed.A combination of bioinformatics, gene deletion, mass spectrometry and metabolic radiolabeling served to show a role for AglR in archaeal N-glycosylation at both the dolichol phosphate and reporter glycoprotein levels.The modified behavior of the S-layer glycoprotein isolated from cells lacking AglR points to an involvement of this protein in N-glycosylation. In cells lacking AglR, glycan-charged dolichol phosphate, including mannose-charged dolichol phosphate, accumulates. At the same time, the S-layer glycoprotein does not incorporate mannose, the final subunit of the N-linked pentasaccharide decorating this protein. AglR is a homologue of Wzx proteins, annotated as flippases responsible for delivering lipid-linked O-antigen precursor oligosaccharides across the bacterial plasma membrane during lipopolysaccharide biogenesis.The effects resulting from aglR deletion are consistent with AglR interacting with dolichol phosphate-mannose, possibly acting as a dolichol phosphate-mannose flippase or contributing to such activity.Little is known of how lipid-linked oligosaccharides are translocated across membrane during N-glycosylation. The possibility of Hfx. volcanii AglR mediating or contributing to flippase activity could help address this situation.

Published

2012

6. Distinct glycan-charged phosphodolichol carriers are required for the assembly of the pentasaccharide N-linked to the Haloferax volcanii S-layer glycoprotein

Author

Shai Naparstek, Jerry Eichler, Ziqiang Guan, Zvia Konrad, and Lina Kaminski

Subjects

chemistry.chemical_classification, Glycan, Glycosylation, Haloferax volcanii, Mannose, Biology, biology.organism_classification, Microbiology, carbohydrates (lipids), chemistry.chemical_compound, Dolichol, chemistry, Biochemistry, Glycosyltransferase, biology.protein, lipids (amino acids, peptides, and proteins), Glycoprotein, Molecular Biology, S-layer

Abstract

Summary In Archaea, dolichol phosphates have been implicated as glycan carriers in the N-glycosylation pathway, much like their eukaryal counterparts. To clarify this relation, highly sensitive liquid chromatography/mass spectrometry was employed to detect and characterize glycan-charged phosphodolichols in the haloarchaeon Haloferax volcanii. It is reported that Hfx. volcanii contains a series of C55 and C60 dolichol phosphates presenting saturated isoprene subunits at the α and ω positions and sequentially modified with the first, second, third and methylated fourth sugar subunits comprising the first four subunits of the pentasaccharide N-linked to the S-layer glycoprotein, a reporter of N-glycosylation. Moreover, when this glycan-charged phosphodolichol pool was examined in cells deleted of agl genes encoding glycosyltransferases participating in N-glycosylation and previously assigned roles in adding pentasaccharide residues one to four, the composition of the lipid-linked glycans was perturbed in the identical manner as was S-layer glycoprotein N-glycosylation in these mutants. In contrast, the fifth sugar of the pentasaccharide, identified as mannose in this study, is added to a distinct dolichol phosphate carrier. This represents the first evidence that in Archaea, as in Eukarya, the oligosaccharides N-linked to glycoproteins are sequentially assembled from glycans originating from distinct phosphodolichol carriers.

Published

2010

7. AglP is a S-adenosyl-L-methionine-dependent methyltransferase that participates in the N-glycosylation pathway ofHaloferax volcanii

Author

Anne Dell, Hilla Magidovich, Zvia Konrad, Sophie Yurist-Doutsch, Jerry Eichler, Valeria V. Ventura, and Paul G. Hitchen

Subjects

chemistry.chemical_classification, Glycosylation, Methyltransferase, Archaeal Proteins, Hexuronic Acids, Haloferax volcanii, Methyltransferases, Biology, biology.organism_classification, Microbiology, Mass Spectrometry, N-linked glycosylation, Biochemistry, chemistry, Asparagine, Selenomethionine, Glycoprotein, Molecular Biology, Gene, Gene Deletion, Function (biology), Archaea

Abstract

While pathways for N-glycosylation in Eukarya and Bacteria have been solved, considerably less is known of this post-translational modification in Archaea. In the halophilic archaeon Haloferax volcanii, proteins encoded by the agl genes are involved in the assembly and attachment of a pentasaccharide to select asparagine residues of the S-layer glycoprotein. AglP, originally identified based on the proximity of its encoding gene to other agl genes whose products were shown to participate in N-glycosylation, was proposed, based on sequence homology, to serve as a methyltransferase. In the present report, gene deletion and mass spectrometry were employed to reveal that AglP is responsible for adding a 14 Da moiety to a hexuronic acid found at position four of the pentasaccharide decorating the Hfx. volcanii S-layer glycoprotein. Subsequent purification of a tagged version of AglP and development of an in vitro assay to test the function of the protein confirmed that AglP is a S-adenosyl-L-methionine-dependent methyltransferase.

Published

2010

8. Synergism between the chaperone-like activity of the stress regulated ASR1 protein and the osmolyte glycine-betaine

Author

Dudy Bar-Zvi and Zvia Konrad

Subjects

Plant Science, Biology, chemistry.chemical_compound, Betaine, Solanum lycopersicum, Genetics, Denaturation (biochemistry), Gene, Heat-Shock Proteins, Plant Proteins, L-Lactate Dehydrogenase, Abiotic stress, food and beverages, Drug Synergism, Kinetics, Cytosol, chemistry, Biochemistry, Spectrophotometry, Osmolyte, Chaperone (protein), biology.protein, Biophysics, Osmoprotectant, Abscisic Acid, Molecular Chaperones

Abstract

Abiotic stress may result in protein denaturation. To confront protein inactivation, plants activate protective mechanisms that include chaperones and chaperone-like proteins, and low-molecular weight organic molecules, known as osmolytes or compatible solutes. If these protective processes fail, the irreversibly damaged proteins are targeted for degradation. Tomato ASR1 (SlASR1) is encoded by a plant-specific gene. Steady state levels of transcripts and protein are transiently induced by salt and water stress in an ABA-dependent manner. SlASR1 is localized in both the cytosol as unstructured monomers and in the nucleus as structured DNA-bound dimers. We show here that the unstructured form of SlASR1 has chaperone-like activity and can stabilize a number of proteins against denaturation caused by heat and freeze-thaw cycles. The protective activity of SlASR1 is synergistic with that of the osmolyte glycine-betaine, which accumulates under stress conditions. We suggest that the cytosolic pool of ASR1 protects proteins from denaturation.

Published

2008

9. Desiccation and Zinc Binding Induce Transition of Tomato Abscisic Acid Stress Ripening 1, a Water Stress- and Salt Stress-Regulated Plant-Specific Protein, from Unfolded to Folded State

Author

Slava Rom, Yehuda Goldgur, Doron Shkolnik, Dudy Bar-Zvi, Zvia Konrad, Natalia Shadrin, and Rodolfo Ghirlando

Subjects

Isothermal microcalorimetry, Circular dichroism, Physiology, Chemistry, Size-exclusion chromatography, chemistry.chemical_element, Plant Science, Zinc, medicine.disease_cause, chemistry.chemical_compound, Monomer, Dynamic light scattering, Biochemistry, Genetics, medicine, Escherichia coli, Abscisic acid

Abstract

Abscisic acid stress ripening 1 (ASR1) is a low molecular weight plant-specific protein encoded by an abiotic stress-regulated gene. Overexpression of ASR1 in transgenic plants increases their salt tolerance. The ASR1 protein possesses a zinc-dependent DNA-binding activity. The DNA-binding site was mapped to the central part of the polypeptide using truncated forms of the protein. Two additional zinc-binding sites were shown to be localized at the amino terminus of the polypeptide. ASR1 protein is presumed to be an intrinsically unstructured protein using a number of prediction algorithms. The degree of order of ASR1 was determined experimentally using nontagged recombinant protein expressed in Escherichia coli and purified to homogeneity. Purified ASR1 was shown to be unfolded using dynamic light scattering, gel filtration, microcalorimetry, circular dichroism, and Fourier transform infrared spectrometry. The protein was shown to be monomeric by analytical ultracentrifugation. Addition of zinc ions resulted in a global change in ASR1 structure from monomer to homodimer. Upon binding of zinc ions, the protein becomes ordered as shown by Fourier transform infrared spectrometry and microcalorimetry, concomitant with dimerization. Tomato (Solanum lycopersicum) leaf soluble ASR1 is unstructured in the absence of added zinc and gains structure upon binding of the metal ion. The effect of zinc binding on ASR1 folding and dimerization is discussed.

Published

2006

10. Mapping the DNA- and zinc-binding domains of ASR1 (abscisic acid stress ripening), an abiotic-stress regulated plant specific protein

Author

Slava Rom, Yossi Kalifa, Ayelet Gilad, Dudy Bar-Zvi, Yehuda Goldgur, Mark Karpasas, and Zvia Konrad

Subjects

Proteases, Amino Acid Motifs, Molecular Sequence Data, Protein domain, chemistry.chemical_element, Zinc, Peptide Mapping, Biochemistry, chemistry.chemical_compound, Solanum lycopersicum, Amino Acid Sequence, Abscisic acid, Plant Proteins, Base Sequence, Abiotic stress, DNA, General Medicine, Plant cell, Protein Structure, Tertiary, DNA-Binding Proteins, chemistry, Acid hydrolysis, Abscisic Acid

Abstract

Abscisic acid stress ripening (ASR1) is a highly charged low molecular weight plant specific protein that is regulated by salt- and water-stresses. The protein possesses a zinc-dependent DNA-binding activity (Kalifa et al., Biochem. J. 381 (2004) 373) and overexpression in transgenic plants results in an increased salt-tolerance (Kalifa et al., Plant Cell Environ. 27 (2004) 1459). There are no structure homologs of ASR1, thus the structural and functional domains of the protein cannot be predicted. Here, we map the protein domains involved in the binding of Zn(2+) and DNA. Using mild acid hydrolysis, and a series of ASR1 carboxy-terminal truncations we show that the zinc-dependent DNA-binding could be mapped to the central/carboxy-terminal domain. In addition, using MALDI-TOF-MS with a non-acidic matrix, we show that two zinc ions are bound to the amino-terminal domain. Other zinc ion(s) bind the DNA-binding domain. Binding of zinc to ASR1 induces conformational changes resulting in a decreased sensitivity to proteases.

Published

2006

11. Over-expression of the water and salt stress-regulated Asr1 gene confers an increased salt tolerance

Author

Zvia Konrad, Yossi Kalifa, E. Perlson, Pablo A. Scolnik, Dudy Bar-Zvi, and Ayelet Gilad

Subjects

Messenger RNA, Physiology, fungi, food and beverages, Plant Science, Biology, biology.organism_classification, Salinity, chemistry.chemical_compound, chemistry, Biochemistry, Gene expression, Proline, Abscisic acid, Ethylene glycol, Gene, Solanaceae

Abstract

ASR1 is a plant-specific, highly charged, low molecular weight polypeptide. Purified ASR1 was shown to posses sequence specific Zn 2+ + + -dependent DNA binding activity (Kalifa et al . Biochemical Journal 381, 373-378, 2004). Steady-state levels of tomato Asr1 mRNA and protein are transiently increased following exposure of plants to poly- ethylene glycol, NaCl or abscisic acid. The biological role of ASR1 could not be deduced from sequence analyses or sequence homologies. Tobacco plants over-expressing tomato ASR1 have a decreased rate of water loss and improved salt tolerance. Upon exposure to salt, ASR1- over-expressing plants accumulate less Na + + + and proline than wild-type plants, and also results in increased steady- state levels of other gene products under non-stressed plant growth conditions. Therefore, ASR1 is probably involved in the regulation of water- or salt-stress-modulated gene expression.

Published

2004

12. The water- and salt-stress-regulated Asr1 (abscisic acid stress ripening) gene encodes a zinc-dependent DNA-binding protein

Author

Yossi Kalifa, Zvia Konrad, Pablo A. Scolnik, Ayelet Gilad, Dudy Bar-Zvi, and Michele Zaccai

Subjects

DNA, Plant, Sodium Chloride, Biology, Cell Fractionation, medicine.disease_cause, Biochemistry, chemistry.chemical_compound, Solanum lycopersicum, Western blot, Gene Expression Regulation, Plant, medicine, Binding site, Molecular Biology, Gene, Abscisic acid, Escherichia coli, Plant Proteins, Zinc finger, Messenger RNA, Binding Sites, medicine.diagnostic_test, Water, food and beverages, Zinc Fingers, Cell Biology, DNA-Binding Proteins, chemistry, Systematic evolution of ligands by exponential enrichment, Subcellular Fractions, Research Article

Abstract

Tomato (Lycopersicon esculantum) ASR1 (abscisic acid stress ripening protein), a small plant-specific protein whose cellular mode of action defies deduction based on its sequence or homology analyses, is one of numerous plant gene products with unknown biological roles that become over-expressed under water- and salt-stress conditions. Steady-state cellular levels of tomato ASR1 mRNA and protein are transiently increased following exposure of plants to poly(ethylene glycol), NaCl or abscisic acid. Western blot and indirect immunofluorescence analysis with anti-ASR1 antibodies demonstrated that ASR1 is present both in the cytoplasmic and nuclear subcellular compartments; approx. one-third of the total ASR1 protein could be detected in the nucleus. Nuclear ASR1 is a chromatin-bound protein, and can be extracted with 1 M NaCl, but not with 0.5% Triton X-100. ASR1, overexpressed in Escherichia coli and purified to homogeneity, possesses zinc-dependent DNA-binding activity. Competitive-binding experiments and SELEX (systematic evolution of ligands by exponential enrichment) analysis suggest that ASR1 binds at a preferred DNA sequence.

Published

2004

13. Isolation of fusion proteins containing SecY and SecE, components of the protein translocation complex from the halophilic archaeon Haloferax volcanii

Author

Jerry Eichler, Gabriela Ring, Zvia Konrad, Vered Irihimovitch, and Tsiona Elkayam

Subjects

Archaeal Proteins, Recombinant Fusion Proteins, Immunoblotting, Gene Expression, digestive system, Microbiology, Genes, Archaeal, Cellulosome, Plasmid, Cellulose, Haloferax volcanii, Halobacteriales, Base Sequence, biology, Escherichia coli Proteins, General Medicine, biology.organism_classification, Fusion protein, digestive system diseases, Transport protein, Molecular Weight, Protein Transport, DNA, Archaeal, surgical procedures, operative, Biochemistry, Molecular Medicine, Clostridium thermocellum, SEC Translocation Channels

Abstract

By exploiting the salt-insensitive interaction of the cellulose-binding domain (CBD) of the Clostridium thermocellum cellulosome with cellulose, purification of CBD-fused versions of SecY and SecE, components of the translocation apparatus of the halophilic archaeon Haloferax volcanii, was undertaken. Following transformation of Haloferax volcanii cells with CBD-SecY- or -SecE-encoding plasmids, cellulose-based purification led to the capture of stably expressed, membrane-bound 68 and 25 kDa proteins, respectively. Both fusion proteins were recognized by antibodies raised against the CBD. Thus, CBD-cellulose interactions can be employed as a salt-insensitive affinity purification system for the capture of complexes containing the Haloferax volcanii translocation apparatus components SecY and SecE.

Published

2003

14. Protein glycosylation inHaloferax volcanii: partial characterization of a 98-kDa glycoprotein

Author

Jerry Eichler and Zvia Konrad

Subjects

chemistry.chemical_classification, Glycosylation, biology, Tunicamycin, Cell Membrane, Haloferax volcanii, Lectin, biology.organism_classification, Microbiology, Anti-Bacterial Agents, Haloferax mediterranei, chemistry.chemical_compound, Bacitracin, chemistry, Biochemistry, Concanavalin A, Genetics, biology.protein, Glycoprotein, Molecular Biology, S-layer, Glycoproteins

Abstract

The plasma membrane of Haloferax volcanii contains several glycoproteins, including a 98-kDa species. Using lectin-based chromatography, the glycoprotein was isolated and partially characterized. Sequence comparison, based on antibody binding as well as one-dimensional peptide maps show that the 98-kDa glycoprotein is distinct from the S-layer glycoprotein, the major glycoprotein in H. volcanii. The 98-kDa glycoprotein can be further distinguished from the S-layer glycoprotein on the basis of membrane attachment. Unlike the S-layer glycoprotein, the 98-kDa glycoprotein is not associated with the membrane in a Mg2+-dependent manner. Both proteins, however, apparently rely on a similar mechanism of glycosylation, since neither was affected by treatment with bacitracin or tunicamycin, agents known to interfere with protein glycosylation in other species. Finally, the pattern of glycosylation of the 98-kDa glycoprotein is not shared by a 95-kDa glycoprotein of the related Haloferax mediterranei strain.

Published

2002

15. N-glycosylation in Haloferax volcanii: adjusting the sweetness

Author

Lina Kaminski, Lina Kandiba, Chen Cohen-Rosenzweig, Zvia Konrad, Jerry Eichler, and Adi Arbiv

Subjects

Microbiology (medical), Glycan, Glycosylation, lcsh:QR1-502, N-glycosylation, Microbiology, lcsh:Microbiology, Mini Review Article, chemistry.chemical_compound, N-linked glycosylation, protein glycosylation, Tetrasaccharide, Asparagine, Haloferax volcanii, chemistry.chemical_classification, biology, S-layer glycoprotein, biology.organism_classification, Archaea, carbohydrates (lipids), chemistry, Biochemistry, post-translational modification, biology.protein, Target protein, Glycoprotein

Abstract

Long believed to be restricted to Eukarya, it is now known that cells of all three domains of life perform N-glycosylation, the covalent attachment of glycans to select target protein asparagine residues. Still, it is only in the last decade that pathways of N-glycosylation in Archaea have been delineated. In the haloarchaeon Haloferax volcanii, a series of Agl (archaeal glycosylation) proteins is responsible for the addition of an N-linked pentasaccharide to modified proteins, including the surface (S)-layer glycoprotein, the sole component of the surface layer surrounding the cell. The S-layer glycoprotein N-linked glycosylation profile changes, however, as a function of surrounding salinity. Upon growth at different salt concentrations, the S-layer glycoprotein is either decorated by the N-linked pentasaccharide introduced above or by both this pentasaccharide as well as a tetrasaccharide of distinct composition. Recent efforts have identified Agl5-Agl15 as components of a second Hfx. volcanii N-glycosylation pathway responsible for generating the tetrasaccharide attached to S-layer glycoprotein when growth occurs in 1.75 M but not 3.4 M NaCl-containing medium.

Published

2013

16. Salty and Sweet: Protein Glycosylation in Haloferax volcanii

Author

Shai Naparstek, Zvia Konrad, Doron Calo, Hilla Magidovich, Jerry Eichler, Lina Kaminski, Sophie Yurist-Doutsch, and Lina Kandiba

Subjects

chemistry.chemical_classification, Protein glycosylation, biology, chemistry, Haloferax volcanii, Halobacterium salinarum, Haloarchaea, Computational biology, biology.organism_classification, Glycoprotein, Genome, Molecular analysis, Archaea

Abstract

Ever since the discovery of the first glycosylated archaeal protein, namely the Halobacterium salinarum surface-layer glycoprotein some 35 years ago, research on haloarchaea has been at the forefront of efforts to decipher the archaeal version of N-glycosylation, a universal post-translational modification. Now, with the availability of sufficient numbers of genome sequences and the development of appropriate experimental tools, the possibility for detailed molecular analysis of archaeal N-glycosylation pathways is being realized, using haloarchaeal species as model systems. In this chapter, current understanding of N-glycosylation in Archaea and the contribution of studies on Haloferax volcanii to such endeavors are described.

Published

2011

17. The Cell Envelopes of Haloarchaea: Staying in Shape in a World of Salt

Author

Zvia Konrad, Noa Plavner, Sophie Yurist-Doutsch, Jerry Eichler, Mehtap Abu-Qarn, and Hilla Magidovich

Subjects

chemistry.chemical_classification, biology, Cell, Salt (chemistry), Polymer, biology.organism_classification, Cell wall, medicine.anatomical_structure, chemistry, Botany, Haloarchaea, medicine, Biophysics, Cell envelope

Abstract

The haloarchaea possess various cell envelope types, composed of different polymers such as S-layers, heteropolysaccharides, or glutaminylglucans. These cell wall polymers are described below.

Published

2010

18. Cloning, Expression, and Purification of Functional Sec11a and Sec11b, Type I Signal Peptidases of the Archaeon Haloferax volcanii

Author

Vered Irihimovitch, Amir Fine, Zvia Konrad, Jerry Eichler, and Idit Dahan

Subjects

Signal peptide, Halobacteriales, Signal peptidase, biology, Archaeal Proteins, Haloferax volcanii, Molecular Sequence Data, Serine Endopeptidases, Membrane Proteins, Sequence alignment, biology.organism_classification, Microbiology, Enzymes and Proteins, Biochemistry, Genome, Archaeal, Amino Acid Sequence, Cloning, Molecular, Molecular Biology, Gene, Peptide sequence, Sequence Alignment, Archaea

Abstract

Across evolution, type I signal peptidases are responsible for the cleavage of secretory signal peptides from proteins following their translocation across membranes. In Archaea , type I signal peptidases combine domain-specific features with traits found in either their eukaryal or bacterial counterparts. Eukaryal and bacterial type I signal peptidases differ in terms of catalytic mechanism, pharmacological profile, and oligomeric status. In this study, genes encoding Sec11a and Sec11b, two type I signal peptidases of the halophilic archaeon Haloferax volcanii , were cloned. Although both genes are expressed in cells grown in rich medium, gene deletion approaches suggest that Sec11b, but not Sec11a, is essential. For purification purposes, tagged versions of the protein products of both genes were expressed in transformed Haloferax volcanii , with Sec11a and Sec11b being fused to a cellulose-binding domain capable of interaction with cellulose in hypersaline surroundings. By employing an in vitro signal peptidase assay designed for use with high salt concentrations such as those encountered by halophilic archaea such as Haloferax volcanii , the signal peptide-cleaving activities of both isolated membranes and purified Sec11a and Sec11b were addressed. The results show that the two enzymes differentially cleave the assay substrate, raising the possibility that the Sec11a and Sec11b serve distinct physiological functions.

Published

2006

19. Protein Translation, Targeting and Translocation in Haloferax Volcanii

Author

Zvia Konrad, Irit Tozik, Jerry Eichler, Vered Irihimovitch, Gabriela Ring, and Tovit Lichi

Subjects

Signal recognition particle, biology, Chemistry, Haloferax volcanii, Membrane binding, Chromosomal translocation, Protein translocation, Protein translation, biology.organism_classification, Signal recognition particle receptor, Cell biology

Published

2005

20. Understanding Archaeal Protein Translocation: Haloferax volcanii as a Model System

Author

Gabriela Ring, Jerry Eichler, and Zvia Konrad

Subjects

Signal recognition particle, biology, Biochemistry, Chemistry, Haloferax volcanii, biology.organism_classification, Gene, Signal recognition particle receptor, Genome, Bacteria, Biogenesis, Archaea

Abstract

The biogenesis of extra-cytoplasmic proteins requires negotiation of the hydrophobic barrier presented by lipid-based membranes. Unlike the well-defined eukaryal and bacterial protein translocation systems, little is known about how proteins cross into and/or across the plasma membrane of Archaea. In Eukarya and Bacteria, protein translocation occurs at membrane sites composed of evolutionarily conserved core proteins acting together with other domain-specific components. Analysis of archaeal genomes and individual genes from other archaeal strains for which no complete genome sequences are available reveals the existence of archaeal homologues of certain elements of the bacterial or eukaryotic systems, as well as the apparent absence of other components of these two systems (Eichler 2000). Thus, while archaeal translocation represents a hybrid of the bacterial and eukaryotic models, closer examination also reveals the existence of archaeal-specific properties. These could be related to the unique chemical composition of the archaeal membrane or to the extreme conditions in which Archaea can exist, including highly saline environments.

Published

2004

21. Lipid modification of proteins in Archaea: attachment of a mevalonic acid-based lipid moiety to the surface-layer glycoprotein of Haloferax volcanii follows protein translocation

Author

Zvia Konrad and Jerry Eichler

Subjects

Glycosylation, Time Factors, Membrane lipids, Protein Prenylation, Mevalonic Acid, Mevalonic acid, Biology, Biochemistry, chemistry.chemical_compound, Haloferax, Magnesium, Molecular Biology, Glycoproteins, chemistry.chemical_classification, Haloferax volcanii, Cell Membrane, Cell Biology, biology.organism_classification, Lipid Metabolism, Archaea, Protein Transport, chemistry, Protein prenylation, Lipid modification, Glycoprotein, Peptides, Acids, Protein Processing, Post-Translational, Research Article

Abstract

Once the newly synthesized surface (S)-layer glycoprotein of the halophilic archaeaon Haloferax volcanii has traversed the plasma membrane, the protein undergoes a membrane-related, Mg2+-dependent maturation event, revealed as an increase in the apparent molecular mass and hydrophobicity of the protein. To test whether lipid modification of the S-layer glycoprotein could explain these observations, H. volcanii cells were incubated with a radiolabelled precursor of isoprene, [3H]mevalonic acid. In Archaea, isoprenoids serve as the major hydrophobic component of archaeal membrane lipids and have been shown to modify other haloarchaeal S-layer glycoproteins, although little is known of the mechanism, site or purpose of such modification. In the present study we report that the H. volcanii S-layer glycoprotein is modified by a derivative of mevalonic acid and that maturation of the protein was prevented upon treatment with mevinolin (lovastatin), an inhibitor of mevalonic acid biosynthesis. These findings suggest that lipid modification of S-layer glycoproteins is a general property of halophilic archaea and, like S-layer glycoprotein glycosylation, lipid-modification of the S-layer glycoproteins takes place on the external cell surface, i.e. following protein translocation across the membrane.

Published

2002