Your search keyword '"Molecular Biophysics Unit"' showing total 12 results

1. Filling-in Void and Sparse Regions in Protein Sequence Space by Protein-Like Artificial Sequences Enables Remarkable Enhancement in Remote Homology Detection Capability

Author

Richa Mudgal, Narayanaswamy Srinivasan, Ramanathan Sowdhamini, Sankaran Sandhya, and Nagasuma Chandra

Subjects

Protein Folding, Protein family, Sequence analysis, In silico, Molecular Sequence Data, Computational biology, Molecular Biophysics Unit, Biology, Bioinformatics, Biochemistry, Homology (biology), Protein sequencing, Sequence Analysis, Protein, Structural Biology, Methionyl Aminopeptidases, Computer Simulation, Amino Acid Sequence, Databases, Protein, Hidden Markov model, Molecular Biology, Peptide sequence, Sequence Homology, Amino Acid, Sequence database, Materials Research Centre, Computational Biology, Proteins, Protein Structure, Tertiary, Phospholipases A2

Abstract

Protein functional annotation relies on the identification of accurate relationships, sequence divergence being a key factor. This is especially evident when distant protein relationships are demonstrated only with three-dimensional structures. To address this challenge, we describe a computational approach to purposefully bridge gaps between related protein families through directed design of protein-like ``linker'' sequences. For this, we represented SCOP domain families, integrated with sequence homologues, as multiple profiles and performed HMM-HMM alignments between related domain families. Where convincing alignments were achieved, we applied a roulette wheel-based method to design 3,611,010 protein-like sequences corresponding to 374 SCOP folds. To analyze their ability to link proteins in homology searches, we used 3024 queries to search two databases, one containing only natural sequences and another one additionally containing designed sequences. Our results showed that augmented database searches showed up to 30% improvement in fold coverage for over 74% of the folds, with 52 folds achieving all theoretically possible connections. Although sequences could not be designed between some families, the availability of designed sequences between other families within the fold established the sequence continuum to demonstrate 373 difficult relationships. Ultimately, as a practical and realistic extension, we demonstrate that such protein-like sequences can be ``plugged-into'' routine and generic sequence database searches to empower not only remote homology detection but also fold recognition. Our richly statistically supported findings show that complementary searches in both databases will increase the effectiveness of sequence-based searches in recognizing all homologues sharing a common fold. (C) 2013 Elsevier Ltd. All rights reserved.

Published

2014

2. T=1 Capsid Structures of Sesbania Mosaic Virus Coat Protein Mutants: Determinants of T=3 and T=1 Capsid Assembly

Author

C.S. Vijay, Sangita, Saravanan, Handanahal S. Savithri, G.L. Lokesh, Mathur R. N. Murthy, and P.S. Satheshkumar

Subjects

Models, Molecular, Static Electricity, Mutant, chemistry.chemical_element, Molecular Biophysics Unit, Calcium, Biology, Crystallography, X-Ray, medicine.disease_cause, Biochemistry, Virus, Mosaic Viruses, Structural Biology, medicine, Asparagine, Protein Structure, Quaternary, Molecular Biology, Escherichia coli, Binding Sites, Virus Assembly, Fabaceae, N-terminus, Protein Subunits, Capsid, chemistry, Mutagenesis, Site-Directed, Biophysics, Capsid Proteins, Protein quaternary structure

Abstract

Sesbania mosaic virus particles consist of 180 coat protein subunits of 29 kDa organized on a T=3 icosahedral lattice. N-terminal deletion mutants of coat protein that lack 36 (CP-N \Delta 36) and 65 (CP-N \Delta 65) residues from the N terminus, when expressed in Escherichia coli, produced similar T=1 capsids of approximate diameter 20 nm. In contrast to the wild-type particles, these contain only 60 copies of the truncated protein subunits (T=1). CP-N \Delta 65 lacks the \beta-annulus believed to be responsible for the error-free assembly of T=3 particles. Though the CP-N \Delta 36 mutant has the b-annulus segment, it does not form a T=3 capsid, presumably because it lacks an arginine-rich motif found close to the amino terminus. Both CPND36 and CP-N \Delta 65 T=1 capsids retain many key features of the T=3 quaternary structure. Calcium binding geometries at the coat protein interfaces in these two particles are also nearly identical. When the conserved aspartate residues that coordinate the calcium, D146 and D149 in the CP-ND65, were mutated to asparagine (CP-N \Delta 65-D146N-D149N), the subunits assembled into T=1 particles but failed to bind calcium ions. The structure of this mutant revealed particles that were slightly expanded. The analysis of the structures of these mutant capsids suggests that although calcium binding contributes substantially to the stability of T=1 particles, it is not mandatory for their assembly. In contrast, the presence of a large fraction of the amino-terminal arm including sequences that precede the \beta-annulus and the conserved D149 appear to be indispensable for the error-free assembly of T=3 particles.

Published

2004

3. Structural Basis for the Carbohydrate Specificities of Artocarpin: Variation in the Length of a Loop as a Strategy for Generating Ligand Specificity

Author

A. Arockia Jeyaprakash, Avadhesha Surolia, Anand Srivastav, and Mamannamana Vijayan

Subjects

Models, Molecular, Stereochemistry, Molecular Sequence Data, Mannose, Molecular Biophysics Unit, Crystallography, X-Ray, Ligands, Substrate Specificity, chemistry.chemical_compound, Structural Biology, Carbohydrate Conformation, Binding site, Protein Structure, Quaternary, Molecular Biology, chemistry.chemical_classification, Binding Sites, Molecular mass, biology, Chemistry, Lectin, Oligosaccharide, Ligand (biochemistry), Mannose-Binding Lectins, Carbohydrate Sequence, Biochemistry, Plant protein, biology.protein, Carbohydrate conformation, Plant Lectins

Abstract

Artocarpin, a tetrameric lectin of molecular mass 65 kDa, is one of the two lectins extracted from the seeds of jackfruit. The structures of the complexes of artocarpin with mannotriose and mannopentose reported here, together with the structures of artocarpin and its complex with Me-alpha-mannose reported earlier, show that the lectin possesses a deep-seated binding site formed by three loops. The binding site can be considered as composed of two subsites; the primary site and the secondary site. Interactions at the primary site composed of two of the loops involve mainly hydrogen bonds, while those at the secondary site comprising the third loop are primarily van der Waals in nature. Mannotriose in its complex with the lectin interacts through all the three mannopyranosyl residues; mannopentose interacts with the protein using at least three of the five mannose residues. The complexes provide a structural explanation for the carbohydrate specificities of artocarpin. A detailed comparison with the sugar complexes of heltuba, the only other mannose-specific jacalin-like lectin with known three-dimensional structure in sugar-bound form, establishes the role of the sugar-binding loop constituting the secondary site, in conferring different specificities at the oligosaccharide level. This loop is four residues longer in artocarpin than in heltuba, providing an instance where variation in loop length is used as a strategy for generating carbohydrate specificity.

Published

2004

4. Structure of Mycobacterium tuberculosis Single-stranded DNA-binding Protein. Variability in Quaternary Structure and Its Implications

Author

Kayarat Saikrishnan, Narottam Acharya, Umesh Varshney, J. Venkatesh, Kanagaraj Sekar, Mamannamana Vijayan, and Jeyaraman Jeyakanthan

Subjects

Models, Molecular, Protein Conformation, Molecular Sequence Data, Oligonucleotides, Electrons, Plasma protein binding, Molecular Biophysics Unit, Biology, Crystallography, X-Ray, chemistry.chemical_compound, Protein structure, BioInformatics Centre, Structural Biology, Escherichia coli, Humans, Scattering, Radiation, Molecular replacement, Amino Acid Sequence, Protein Structure, Quaternary, Molecular Biology, Peptide sequence, Microbiology & Cell Biology, Oligonucleotide, DNA replication, DNA, Mycobacterium tuberculosis, Mitochondria, DNA-Binding Proteins, Crystallography, chemistry, Biophysics, Protein quaternary structure, Peptides, Dimerization, Protein Binding

Abstract

Single-stranded DNA-binding protein (SSB) is an essential protein necessary for the functioning of the DNA replication, repair and recombination machineries. Here we report the structure of the DNA-binding domain of Mycobacterium tuberculosis SSB (MtuSSB) in four different crystals distributed in two forms. The structure of one of the forms was solved by a combination of isomorphous replacement and anomalous scattering. This structure was used to determine the structure of the other form by molecular replacement. The polypeptide chain in the structure exhibits the oligonucleotide binding fold. The globular core of the molecule in different subunits in the two forms and those in Escherichia coli SSB (EcoSSB) and human mitochondrial SSB (HMtSSB) have similar structure, although the three loops exhibit considerable structural variation. However, the tetrameric MtuSSB has an as yet unobserved quaternary association. This quaternary structure with a unique dimeric interface lends the oligomeric protein greater stability, which may be of significance to the functioning of the protein under conditions of stress. Also, as a result of the variation in the quaternary structure the path adopted by the DNA to wrap around MtuSSB is expected to be different from that of EcoSSB.

Published

2003

5. Crystal Structure of the Jacalin–T-antigen Complex and a Comparative Study of Lectin–T-antigen Complexes

Author

G. Banuprakash Reddy, A. Arockia Jeyaprakash, Avadhesha Surolia, Sankaran Banumathi, Mamannamana Vijayan, P. Geetha Rani, Christian Betzel, and Kanagaraj Sekar

Subjects

Models, Molecular, Stereochemistry, Disaccharide, Molecular Biophysics Unit, Crystallography, X-Ray, Substrate Specificity, chemistry.chemical_compound, Tetramer, Antigen, BioInformatics Centre, Structural Biology, Lectins, Carbohydrate Conformation, Antigens, Tumor-Associated, Carbohydrate, Binding site, Protein Structure, Quaternary, Molecular Biology, Binding Sites, Molecular mass, biology, Chemistry, Galactose, Lectin, Hydrogen Bonding, Protein Structure, Tertiary, Oxygen, Protein Subunits, Biochemistry, Plant protein, Jacalin, biology.protein, Plant Lectins, Crystallization, Artocarpus

Abstract

Thomsen–Friedenreich antigen (Galbeta1–3GalNAc), generally known as T-antigen, is expressed in more than 85% of human carcinomas. Therefore, proteins which specifically bind T-antigen have potential diagnostic value. Jacalin, a lectin from jack fruit (Artocarpus integrifolia ) seeds, is a tetramer of molecular mass 66 kDa. It is one of the very few proteins which are known to bind T-antigen. The crystal structure of the jacalin–T-antigen complex has been determined at 1.62 A° resolution. The interactions of the disaccharide at the binding site are predominantly through the GalNAc moiety, with Gal interacting only through water molecules. They include a hydrogen bond between the anomeric oxygen of GalNAc and the pie electrons of an aromatic side-chain. Several intermolecular interactions involving the bound carbohydrate contribute to the stability of the crystal structure. The present structure, along with that of the Me-alpha-Gal complex, provides a reasonable qualitative explanation for the known affinities of jacalin to different carbohydrate ligands and a plausible model of the binding of the lectin to T-antigen O-linked to seryl or threonyl residues. Including the present one, the structures of five lectin–T-antigen complexes are available. GalNAc occupies the primary binding site in three of them, while Gal occupies the site in two. The choice appears to be related to the ability of the lectin to bind sialylated sugars. In either case, most of the lectin–disaccharide interactions are at the primary binding site. The conformation of T-antigen in the five complexes is nearly the same.

Published

2002

6. Three-dimensional Structure of Physalis Mottle Virus: Implications for the Viral Assembly

Author

C. N. Hiremath, Handanahal S. Savithri, Sanjay Krishna, S. K. Munshi, Mathur R. N. Murthy, D. Prahadeeswaran, and Mira Sastri

Subjects

Protein Folding, Protein Conformation, Protein subunit, Molecular Sequence Data, Molecular Biophysics Unit, Biochemistry, Sobemovirus, Viral Proteins, Capsid, Structural Biology, Plant virus, Molecular replacement, Amino Acid Sequence, Tymovirus, Molecular Biology, Peptide sequence, Turnip yellow mosaic virus, Sequence Homology, Amino Acid, biology, Virus Assembly, Capsomere, biology.organism_classification, Crystallography, Capsid Proteins, Peptides

Abstract

The structure of the T=3 single stranded RNA tymovirus, physalis mottle virus (PhMV), has been determined to 3.8\AA resolution. PhMV crystals belong to the rhombohedral space group R 3, with one icosahedral particle in the unit cell leading to 20-fold non-crystallographic redundancy. Polyalanine coordinates of the related turnip yellow mosaic virus (TYMV) with which PhMV coat protein shares 32 % amino acid sequence identity were used for obtaining the initial phases. Extensive phase refinement by real space molecular replacement density averaging resulted in an electron density map that revealed density for most of the side-chains and for the 17 residues ordered in PhMV, but not seen in TYMV, at the N terminus of the A subunits. The core secondary and tertiary structures of the subunits have a topology consistent with the capsid proteins of other T=3 plant viruses. The N-terminal arms of the A subunits, which constitute 12 pentamers at the icosahedral 5-fold axes, have a conformation very different from the conformations observed in B and C subunits that constitute hexameric capsomers with near 6-fold symmetry at the icosahedral 3-fold axes. An analysis of the interfacial contacts between protein subunits indicates that the hexamers are held more strongly than pentamers and hexamer-hexamer contacts are more extensive than pentamer-hexamer contacts. These observations suggest a plausible mechanism for the formation of empty capsids, which might be initiated by a change in the conformation of the N-terminal arm of the A subunits. The structure also provides insights into immunological and mutagenesis results. Comparison of PhMV with the sobemovirus, sesbania mosaic virus reveals striking similarities in the overall tertiary fold of the coat protein although the capsid morphologies of these two viruses are very different.

Published

1999

7. Structure of Sesbania Mosaic Virus at 4·7 Å Resolution and Partial Sequence of the Coat Protein

Author

M.V. Nayudu, Mathur R. N. Murthy, H.S. Subramanya, Handanahal S. Savithri, and K. Gopinath

Subjects

chemistry.chemical_classification, Cation binding, food.dish, Icosahedral symmetry, Molecular Sequence Data, Resolution (electron density), Sesbania grandiflora, Molecular Biophysics Unit, Biology, Biochemistry, Amino acid, Crystallography, Capsid, food, X-Ray Diffraction, chemistry, Mosaic Viruses, Structural Biology, Plant virus, Aspartic acid, Trypsin, Amino Acid Sequence, Molecular Biology, Peptide sequence

Abstract

Sesbania mosaic virus (SMV) is a plant virus infecting Sesbania grandiflora plants in Andhra Pradesh, India. Amino acid sequence of the tryptic peptides of SMV coat protein were determined using a gas phase sequenator. These sequences showed identical amino acids at 69% of the positions when aligned with the corresponding residues of southern bean mosaic virus (SBMV). Crystals diffracting to better than 3 A resolution were obtained by precipitating the virus with ammonium sulphate. The crystals belonged to rhombohedral space group R3 with a = 291.4 A and alpha = 61.9 degrees. Three-dimensional X-ray diffraction data on these crystals were collected to a resolution of 4.7 A, using a Siemens-Nicolet area detector system. Self-rotation function studies revealed the icosahedral symmetry of the virus particles, as well as their precise orientation in the unit cell. Cross-rotation function and modelling studies with SBMV showed that it is a valid starting model for SMV structure determination. Low resolution phases computed using a polyalanine model of SBMV were subjected to refinement and extension by real-space electron density averaging and solvent flattening. The final electron density map revealed a polypeptide fold similar to SBMV. The single disulphide bridge of SBMV coat protein is retained in SMV. Four icosahedrally independent cation binding sites have been tentatively identified. Three of these sites, related by a quasi threefold axis, are also found in SBMV. The fourth site is situated on the quasi threefold axis. Aspartic acid residues, which replace Ile218 of SBMV from the quasi threefold-related subunits are suitable ligands to the cation at this site.

Published

1993

8. Snapshots of RecA protein involving movement of the C-domain and different conformations of the DNA-binding loops: crystallographic and comparative analysis of 11 structures of Mycobacterium smegmatis RecA

Author

J. Rajan Prabu, Kalappa Muniyappa, Mamannamana Vijayan, Ramadas Krishna, G.P. Manjunath, Sunando Datta, and Nagasuma Chandra

Subjects

Models, Molecular, Protein Folding, Protein Conformation, Mycobacterium smegmatis, Glycine, Molecular Biophysics Unit, medicine.disease_cause, Crystallography, X-Ray, Biochemistry, Protein filament, chemistry.chemical_compound, Structural Biology, BioInformatics Centre, medicine, Nucleotide, SOS response, Supercomputer Education & Research Centre, Molecular Biology, Escherichia coli, chemistry.chemical_classification, Binding Sites, biology, Intermolecular force, biology.organism_classification, Protein Structure, Tertiary, DNA-Binding Proteins, Crystallography, Rec A Recombinases, chemistry, Recombination, DNA

Abstract

Mycobacterium smegmatis RecA and its nucleotide complexes crystallize in three different, but closely related, forms characterized by specific ranges of unit cell dimensions. The six crystals reported here and five reported earlier,all grown under the same or very similar conditions, belong to these three forms, all in space group $P6_1$. They include one obtained by reducing relative humidity around the crystal. In all crystals, RecA monomers form filaments around a $6_1$ screw axis. Thus, the c-dimension of the crystal corresponds to the pitch of the RecA filament. As reported for Escherichia coli RecA, the variation in the pitch among the three forms correlates well with the motion of the C-terminal domain of the RecA monomers with respect to the main domain. The domain motion is compatible with formation of inactive as well as active RecA filaments involving monomers with a fully ordered C domain. It does not appear to influence the movement upon nucleotide-binding of the switch residue, which is believed to provide the trigger for transmitting the effect of nucleotide binding to the DNA-binding region. Interestingly, partial dehydration of the crystal results in the movement of the residue similar to that caused by nucleotide binding. The ordering of the DNA-binding loops, which present ensembles of conformations, is also unaffected by domain motion. The conformation of loop L2 appears to depend upon nucleotide binding,presumably on account of the movement of the switch residue that forms part of the loop. The conformations of loops L1 and L2 are correlated and have implications for intermolecular communications within the RecA filament. The structures resulting from different orientations of the C domain and different conformations of the DNA-binding loops appear to represent snapshots of the RecA at different phases of activity, and provide insights into the mechanism of action of RecA.

Published

2006

9. X-ray structural studies of Mycobacterium tuberculosis RRF and a comparative study of RRFs of known structure. Molecular plasticity and biological implications

Author

Mamannamana Vijayan, Kayarat Saikrishnan, Umesh Varshney, and S. K. Kalapala

Subjects

Helix bundle, Microbiology & Cell Biology, Models, Molecular, Ribosomal Proteins, Conformational change, Protein Conformation, Static Electricity, Ribosome Recycling Factor, Proteins, Crystal structure, Mycobacterium tuberculosis, Biology, Molecular Biophysics Unit, Rotation, Crystallography, X-Ray, Structural genomics, Crystallography, Bacterial Proteins, X-Ray Diffraction, Structural Biology, Domain (ring theory), biology.protein, Libration (molecule), Molecular Biology

Abstract

The crystal structure of Mycobacterium tuberculosis ribosome recycling factor has been determined and refined against three X-ray diffraction data sets, two collected at room temperature and the other at 100K. The two room-temperature data sets differ in the radiation damage suffered by the crystals before the data used for processing were collected. A comparison between the structures refined against the two data sets indicates the possibility of radiation-induced conformational change. The L-shaped molecule is composed of a long three-helix bundle domain (domain I) and a globular domain (domain II) connected by a linker region. The main difference between the room-temperature structure and the low temperature structure is in the rotation of domain II about an axis close to its libration axis. This observation and a detailed comparative study of ribosome recycling factors (RRFs) of known structures led to an elaboration of the present understanding of the structural variability of RRF. The variability involves a change in the angle between the two arms of the molecule, a rotation of domain II in a plane nearly perpendicular to the axis of the helix bundle and an internal rotation of domain II. Furthermore, the domains and the linker could be delineated into fixed and variable regions in a physically meaningful manner. The relative mobility of the domains of the molecule in the crystal structure appears to be similar to that in the ribosome--RRF complex. That permits a meaningful discussion of the structural features of RRF in terms of ribosome--RRF interactions. The structure also provides insights into the results of inter-species complementation studies.

Published

2004

10. Structural basis of the carbohydrate specificities of jacalin: an X-ray and modeling study

Author

S. Katiyar, Chittoor P. Swaminathan, Avadhesha Surolia, A. Arockia Jeyaprakash, Kanagaraj Sekar, and Mamannamana Vijayan

Subjects

Steric effects, Models, Molecular, Secondary site, Anomer, Stereochemistry, Carbohydrates, Crystal structure, Molecular Biophysics Unit, Crystallography, X-Ray, Protein Structure, Secondary, Adjuvants, Immunologic, BioInformatics Centre, Structural Biology, Humans, Molecular Biology, Binding Sites, Hydrogen bond, Chemistry, Carbohydrate, Crystallography, Jacalin, Carbohydrate Metabolism, Variable geometry, Plant Lectins, Artocarpus, Protein Binding

Abstract

The structures of the complexes of tetrameric jacalin with Gal, Me-alpha-GalNAc, Me-alpha-T-antigen, GalNAcbeta1-3Gal-alpha-O-Me and Galalpha1-6Glc (mellibiose) show that the sugar-binding site of jacalin has three components: the primary site, secondary site A, and secondary site B. In these structures and in the two structures reported earlier, Gal or GalNAc occupy the primary site with the anomeric carbon pointing towards secondary site A. The alpha-substituents, when present, interact, primarily hydrophobically, with secondary site A which has variable geometry. O-H..., centered pi and C-H...pi hydrogen bonds involving this site also exist. On the other hand, beta-substitution leads to severe steric clashes. Therefore, in complexes involving beta-linked disaccharides, the reducing sugar binds at the primary site with the non-reducing end located at secondary site B. The interactions at secondary site B are primarily through water bridges. Thus, the nature of the linkage determines the mode of the association of the sugar with jacalin. The interactions observed in the crystal structures and modeling based on them provide a satisfactory qualitative explanation of the available thermodynamic data on jacalin-carbohydrate interactions. They also lead to fresh insights into the nature of the binding of glycoproteins by jacalin.

Published

2003

11. Conformation, protein-carbohydrate interactions and a novel subunit association in the refined structure of peanut lectin-lactose complex

Author

Mamannamana Vijayan, Raman Ravishankar, Rahul Banerjee, Kaza Suguna, Avadhesha Surolia, and Kalyan Das

Subjects

Peanut agglutinin, Stereochemistry, Protein subunit, Molecular Sequence Data, Carbohydrates, Lactose, Molecular Biophysics Unit, Crystallography, X-Ray, Protein Structure, Secondary, Peanut Agglutinin, Protein structure, Structural Biology, Lectins, Protein–carbohydrate interactions, Molecular Biology, biology, Chemistry, Hydrogen bond, Proteins, Water, Legume lectin, Hydrogen Bonding, Protein tertiary structure, Protein Structure, Tertiary, Crystallography, Carbohydrate Sequence, Covalent bond, Metals, biology.protein, Carbohydrate Metabolism

Abstract

The structure of the complex of the tetrameric peanut lectin with lactose has been refined to an R-value of 16.4% using 2.25 angstroms resolution X-ray diffraction data. The subunit conformation in the structure is similar to that in other legume lectins except in the loops. It has been shown that in the tertiary structure of legume lectins, the short five-stranded sheet plays a major role in connecting the larger flat six-stranded and curved seven-stranded sheets. Furthermore, the loops that connect the strands at the two ends of the seven-stranded sheet curve toward and interact with each other to produce a second hydrophobic core in addition to the one between the two large sheets. The protein-lactose interactions involve the invariant features observed in other legume lectins in addition to those characteristic of peanut lectin. The "open" quaternary association in peanut lectin is stabilised by hydrophobic, hydrogen-bonded and water-mediated interactions. Contrary to the earlier belief, the structure of peanut lectin demonstrates that the variability in quaternary association in legume lectins, despite all of them having nearly the same tertiary structure, is not necessarily caused by covalently bound carbohydrate. An attempt has been made to provide a structural rationale for this variability, on the basis of buried surface areas during dimerisation. A total of 45 water molecules remain invariant when the hydration shells of the four subunits are compared. A majority of them appear to be involved in stabilising loops.

Published

1996

12. Recognition of B and Z forms of DNA by Escherichia coli DNA polymerase I

Author

N. Ramesh, Samir K. Brahmachari, and Y. S. Shouche

Subjects

DNA, Bacterial, DNA clamp, biology, DNA polymerase, DNA polymerase II, DNA replication, Templates, Genetic, Molecular Biophysics Unit, DNA Polymerase I, DNA polymerase delta, Molecular biology, Substrate Specificity, Structural Biology, biology.protein, Escherichia coli, Nucleic Acid Conformation, DNA polymerase I, Molecular Biology, DNA polymerase mu, Polymerase

Abstract

Since the substrate binding domain of the large proteolytic fragment of Escherichia coli DNA polymerase I has been shown to interact with the B forms of DNA, we have studied the ability of this enzyme to recognize structures other than the B form. The polymerase activity has been used to evaluate the degree of recognition of the B and Z forms of DNA. The Z form was found to promote less activity, indicating the probable inability of the polymerase to move along the conformationally rigid form of the template. The present study indicates that the Z-DNA found in vivo may have a role in the control of replication.

Published

1986