Mechanical activation of cells induces chromatin remodeling preceding MKL nuclear transport.

For cells to adapt to different tissues and changes in tissue mechanics, they must be able to respond to mechanical cues by changing their gene expression patterns. Biochemical signaling pathways for these responses have been elucidated, and recent evidence points to the involvement of force-induced deformation of the nucleus. However, it is still unclear how physical cues received at the plasma membrane (PM) spatiotemporally integrate to the functional chromatin organization of the cell nucleus. To investigate this issue, we applied mechanical forces through magnetic particles adhered to the PM of single cells and mapped the accompanying changes in actin polymerization, nuclear morphology, chromatin remodeling, and nuclear transport of soluble signaling intermediates using high-resolution fluorescence anisotropy imaging. Using this approach, we show the timescales associated with force-induced polymerization of actin and changes in the F/G actin ratio resulting in nuclear translocation of the G-actin-associated transcriptional cofactor, megakaryoblastic acute leukemia factor-1 (MKL). Further, this method of measuring nuclear organization at high spatiotemporal resolution with simultaneous force application revealed the physical propagation of forces to the nucleus, resulting in changes to chromatin organization, followed by nuclear deformation. We also describe a quantitative model that incorporates active stresses and chemical kinetics to evaluate the observed timescales. Our work suggests that mechanical activation of cells is accompanied by distinct timescales involved in the reorganization of actin and chromatin assembly, followed by translocation of transcription cofactors from the cytoplasm to the nucleus.

Point mutation affecting processing of the ornithine aminotransferase precursor protein in gyrate atrophy.

A generalized deficiency of the mitochondrial enzyme, ornithine aminotransferase (OAT) is the inborn error in gyrate atrophy, an autosomal recessive degenerative disease of the choroid and retina of the eye that leads to blindness. Southern analysis, using the OAT cDNA probe, of the OAT gene in a gyrate atrophy patient whose level of OAT protein is markedly decreased indicated the functional gene to be grossly intact. Northern analysis of his OAT mRNA demonstrated only half the normal level of OAT message, suggesting expression of only one of the two alleles of the OAT gene. A functional assay of the expressed OAT mRNA by in vitro translation and immunoprecipitation with anti-human OAT antibody indicated synthesis of an OAT protein from the message. The expressed message was cloned and sequenced and was shown to contain a single base change from C to T, resulting in an amino acid codon change from CAT (histidine) to TAT (tyrosine) at position 319 in the translated OAT protein. The mutant and normal OAT precursors were synthesized using transcriptional expression clones of OAT and in vitro translation of the expressed mRNA and tested in an in vitro mitochondrial transport/processing system. The results indicate that the mutant OAT precursor from the gyrate atrophy patient can be transported to the mitochondria but is minimally processed there, which would lead to degradation of the labile precursor and loss of OAT activity as phenotypically observed.

Computer programs in nucleic acid synthesis: synthetic strategy development using solid-phase chemical techniques with data storage, retrieval and analysis capabilities.

A computer program has been designed to aid development of synthetic strategies for oligonucleotides produced by solid-phase chemical techniques. The program reduces the time required to develop a strategy and a data file from hours to minutes. The program contains inventories, provides cost analyses, and generates and stores other associated data. The program searches an inventory of sequences for that sequence to avoid duplicate synthesis. If the sequence is not in the inventory the program devises a synthetic strategy, calculates the amounts of reagents and labor costs necessary to complete the synthetic oligonucleotide. The program also deducts the reagents from inventory files. Physical data is also calculated. A file is generated in a sequence inventory for storage of the data as well as other data that will be generated during the purification processes. All variable parameters can be easily edited. The programs were designed to provide a cross-referencing feature for data analysis and can use several parameters as a constant.

Computer programs in nucleic acid synthesis: synthetic strategy development using solid-phase chemical techniques with data storage, retrieval and analysis capabilities.

A computer program has been designed to aid development of synthetic strategies for oligonucleotides produced by solid-phase chemical techniques. The program reduces the time required to develop a strategy and a data file from hours to minutes. The program contains inventories, provides cost analyses, and generates and stores other associated data. The program searches an inventory of sequences for that sequence to avoid duplicate synthesis. If the sequence is not in the inventory the program devises a synthetic strategy, calculates the amounts of reagents and labor costs necessary to complete the synthetic oligonucleotide. The program also deducts the reagents from inventory files. Physical data is also calculated. A file is generated in a sequence inventory for storage of the data as well as other data that will be generated during the purification processes. All variable parameters can be easily edited. The programs were designed to provide a cross-referencing feature for data analysis and can use several parameters as a constant.

Detection of a guanine X adenine base pair in a decadeoxyribonucleotide by proton magnetic resonance spectroscopy.

A decadeoxyribonucleotide, d(C-C-A-A-G-A-T-T-G-G) (I), forms a duplex in solution. The base pairing pattern in this duplex was studied by proton nuclear magnetic resonance spectroscopy. Five NH...N hydrogen-bonded proton resonances were observed, and they were assigned by nuclear Overhauser enhancement experiments as well as by comparison to five previously assigned NH...N hydrogen-bonded proton resonances in a self-complementary duplex of similar sequence, d(C-C-A-A-G-C-T-T-G-G) (II). The results suggest that the central -G-A- residues of I form G X A base pairs in the helical state. The fact that the H2 proton of A at the sixth position from the 5' end of I showed nuclear Overhauser enhancement when the NH...N hydrogen-bonded proton resonance of G X A was irradiated suggests that the bases of the G X A base pair are oriented in an anti-anti conformation. Comparison of the linewidths at the half height of the NH...N hydrogen-bonded proton resonances of I at 1 degree C suggest that the G X A base pairs are less stable than adjacent A X T base pairs.

Synthesis and template properties of an ethyl phosphotriester modified decadeoxyribonucleotide.

The phosphate groups of nucleic acids are often the targets of mutagenic and carcinogenic alkylating agents. In order to study the effects of alkyl phosphotriester modification on the physical and biochemical properties of DNA, two diastereomeric ethyl phosphotriester modified decadeoxyribonucleotides, d-CpCpApApGp(Et)ApTpTpGpG isomer I and isomer II, were prepared. A phosphotriester synthetic procedure was used to specifically place ethyl triester groups with either an R or S configuration in the central dimer region of the decamer. Terminal deoxynucleotidyl transferase was used to add oligodeoxyadenylate tails to the 3' end of the decamers. The resulting oligomers were tested as templates for Escherichia coli DNA polymerase I with d-(pT)8pCpC as a primer. The rates and extents of polymerization directed by the modified templates were 25% (isomer I) and 50% (isomer II) less than those of an unmodified control template. Thus the presence of an ethyl triester group inhibits polymerization, the effectiveness of which is determined by the orientation of the ethyl group relative to the rest of the template backbone. These results suggest ethyl phosphotriester lesions could inhibit replication rates of cellular DNA.

Oligothymidylate analogues having stereoregular, alternating methylphosphonate/phosphodiester backbones as primers for DNA polymerase.

Oligothymidylate analogues having stereoregular, alternating methylphosphonate/phosphodiester backbones, d-Tp(TpTp)4T isomers I and II and d-Tp(TpTp)3T(pT)1-5 isomers I and II, were prepared by methods analogous to the phosphotriester synthetic technique. The designations isomer I nd isomer II refer to the configuration of the methylphosphonate linkage, which is the same through each isomer. Analogues with the type I methylphosphonate configuration form very stable duplexes with poly(dA) while those with the type II configuration form either 2T:1A triplexes or 1T:1A duplexes with poly(dA) of considerably lower stabilities. The oligothymidylate analogues were tested for their ability to initiate polymerizations catalyzed by Escherichia coli DNA polymerase I or calf thymus DNA polymerase alpha on a poly(dA) template. Neither d-Tp(TpTp)4T nor d-Tp(T]Tp)3TpT served as initiators of polymerization while d-Tp(TpTp)3T(pT)2-5 showed increasing priming ability as the length of the 3'-oligothymidylate tail increased. Analogues with type I methylphosphonate configuration were more effective initiators than the type II analogues at 37 degrees C. The apparent activation energies of polymerizations initiated by d-Tp(TpTp)3T-(pT)4 and 5 isomer I were greater than those for reactions initiated by isomer II or d-(Tp)11T. The results suggest that DNA polymerase interacts with the charged phosphodiester groups of the primer molecule and may help stabilize primer/template interaction. At least two contiguous phosphodiester groups are required at the 3' end of the analogue primers in order for polymerization to occur. Interactions between the polymerase and primer also appear to occur with phosphodiester groups located at sites remote from the 3'-OH polymerization site and may be influenced by the configuration of the methylphosphonate group.

Oligothymidylate analogues having stereoregular, alternating methylphosphonate/phosphodiester backbones. Synthesis and physical studies.

Two decathymidylate analogues, d-(TpTp)4TpT-isomer 1 and isomer 2, having stereoregular, alternating methylphosphonate/phosphodiester backbones were prepared. The phosphodiester linkages of d-(TpTp)4TpT are cleaved slowly by snake venom phosphodiesterase in a stepwise manner, while slow random cleavage occurs with micrococcal nuclease which hydrolyzes isomer 2 faster than isomer 1. The CD spectra of isomer 1 and d-(Tp)9T are identical suggesting they have similar conformations, while that of isomer 2 shows an overall reduction of [theta]. Isomer 1 forms a 1T . 1A complex with poly(dA) and both 1T . 1A and 2T . 1A complexes with poly(rA), while isomer 2 forms a 2T . 1A complex of low thermal stability with poly(dA) and no complex with poly(rA). The Tm values of the partially nonionic d-(TpTp)4TpT . polynucleotide complexes are less dependent on salt concentration than are those of d-(Tp)9T. The stoichiometry and CD spectra of the complexes suggest that poly(dA) . isomer 1 duplex assumes a B-type geometry while isomer 2 . poly(dA) . isomer 2 triplex and the isomer 1 . poly(rA) complexes have an A-type geometry. Although there are no apparent differences between steric restrictions to rotation about the backbones of either isomer 1 or 2, or steric restrictions to complex formation, the results suggest that the configuration of the methylphosphate linkage controls: 1) interaction with nucleases, 2) oligomer conformation, and 3) interaction with polynucleotides. The latter effects may result from differences in solvation of the two isomers.

Preparation of a decadeoxyribonucleotide helix for studies by nuclear magnetic resonance.

A self-complementary decadeoxyribonucleotide d-CpCpApApGpCpTpTpGpG was chemically synthesized by a procedure based on the phosphotriester approach. This procedure was carefully monitored and appropriately modified to ensure the purity of oligomer components at each step of the synthetic scheme. Extensive use was made of both analytical and preparative high-pressure liquid chromatography to purify and characterize the decamer and its constituent oligonucleotides. The final product (1318 A257 units or 16.5 mumol) was obtained in high purity and sufficient quantity for extensive physical studies by UV, CD, and NMR spectroscopy. Our preliminary results show that at a strand concentration of 1.3 X 10(-5) M and in 0.10 M sodium chloride and 0.01 M sodium phosphate buffer, pH 7.0, the decamer duplex has a Tm at 47 degrees C. The CD spectrum of this decamer duplex is similar to that of B-form DNA. All the resonances of the nonexchangeable base protons of the decamer are well resolved in the 1H NMR spectrum, when the single-stranded form was examined by using a 360-MHz spectrometer and when the duplex form was examined by using a 600-MHz spectrometer. These base proton resonances have been tentatively assigned by using the incremental assignment technique. Although the decamer duplex serves as a substrate for AluI restriction endonuclease, it is not cleaved by HindIII endonuclease.