A chloroplast DNA helicase II from pea that prefers fork-like replication structures

Salt tolerant fungal endophytes alleviate the growth and yield of saline-affected wheat genotype PBW-343

The purpose of this work was to assess how salt-tolerant wheat endophytic fungi promoted the growth of salt-sensitive wheat after inoculation. The endophytic fungal assemblages from salt-tolerant wheat genotypes (KRL-213, KRL-210 and KRL-19) and from salt-sensitive wheat genotype (PBW-343) were characterized, identified and determined for the current study. Of the fifty fungal isolates collected from both the salt-tolerant and the salt-sensitive wheat genotypes, 8 isolates recovered from salt-tolerant varieties were found to be resistant at high salt concentrations. These 8 isolates were characterized through several biochemical tests, such as plant growth promoting assay, extracellular enzymatic assay, carbohydrate utilization assay, antagonism versus plants pathogens and capacity to promote wheat seedlings (pot experiments). All tests revealed the positive results for 4 fungal strains (K13TR/150, K19TR/200, K-19TL/150 and K-19TL/200). These 4 fungi were identified as Aspergillus medius (K19TR/200), Cladosporium parahalotolerant (K13TR/150), Aspergillus versicolor (K19TL/150) and Aspergillus nishimurae (K19TL/200) through 18 S rDNA sequencing. Out of these, C. parahalotolerant and A. medius showed the synergistic effect with each other, so these 2 isolates were used in further experiments. These 2 isolates were involved in increasing the root-shoot length, proline and MDA contents. SEM and fluorescence microscopy were used to detect endophytic fungal colonization in the root of seedlings. C. parahalotolerant and A. medius heavily colonized the roots and it was noticed on the 21st day of the growth phase. These findings imply that fungal isolates have the potential to confer stress tolerance to their respective hosts and may enhance the agricultural production in the future, especially considering the changes in climate.

Stress responsive DEAD-box helicases: a new pathway to engineer plant stress tolerance

Abiotic stresses including various environmental factors adversely affect plant growth and limit agricultural production worldwide. Minimizing these losses is a major area of concern for all countries. Therefore, it is desirable to develop multi-stress tolerant varieties. Salinity, drought, and cold are among the major environmental stresses that greatly influence the growth, development, survival, and yield of plants. UV-B radiation of sunlight, which damages the cellular genomes, is another growth-retarding factor. Several genes are induced under the influence of various abiotic stresses. Among these are DNA repair genes, which are induced in response to the DNA damage. Since the stresses affect the cellular gene expression machinery, it is possible that molecules involved in nucleic acid metabolism including helicases are likely to be affected. The light-driven shifts in redox-potential can also initiate the helicase gene expression. Helicases are ubiquitous enzymes that catalyse the unwinding of energetically stable duplex DNA (DNA helicases) or duplex RNA secondary structures (RNA helicases). Most helicases are members of DEAD-box protein superfamily and play essential roles in basic cellular processes such as DNA replication, repair, recombination, transcription, ribosome biogenesis and translation initiation. Therefore, helicases might be playing an important role in regulating plant growth and development under stress conditions by regulating some stress-induced pathways. There are now few reports on the up-regulation of DEAD-box helicases in response to abiotic stresses. Recently, salinity-stress tolerant tobacco plants have already been raised by overexpressing a helicase gene, which suggests a new pathway to engineer plant stress tolerance [N. Sanan-Mishra, X.H. Pham, S.K. Sopory, N. Tuteja, Pea DNA helicase 45 overexpression in tobacco confers high salinity tolerance without affecting yield. Proc. Natl. Acad. Sci. USA 102 (2005) 509-514]. Presently the exact mechanism of helicase-mediated stress tolerance is not understood. In this review we have described all the reported stress-induced helicases and also discussed the possible mechanisms by which they can provide stress tolerance.

The Gly-Arg-rich C-terminal domain of pea nucleolin is a DNA helicase that catalytically translocates in the 5'- to 3'-direction

Nucleolin is a major nucleolar phosphoprotein of exponentially growing eukaryotic cells. Here we report the cloning, purification, and characterization of the C-terminal glycine/arginine-rich (GAR) domain of pea nucleolin. The purified recombinant protein (17 kDa) shows ATP-/Mg(2+)-dependent DNA helicase and ssDNA-/Mg(2+)-dependent ATPase activities. The enzyme unwinds DNA in the 5'- to 3'-direction, which is the first report in plant for this directional activity. It unwinds forked/non-forked DNA with equal efficiency. The anti-nucleolin antibodies immunodepleted the activities of the enzyme. The DNA interacting ligands nogalamycin, daunorubicin, actinomycin C1, and ethidium bromide were inhibitory to DNA unwinding (with K(i) values of 0.40, 2.21, 8.0, and 9.0 microM, respectively) and ATPase (with K(i) values of 0.43, 1.65, 4.6, and 7.0 microM, respectively) activities of the enzyme. This study confirms that the unwinding and ATPase activities of pea nucleolin resided in the GAR domain. This study should make important contribution to our better understanding of DNA transaction in plants, mechanism of DNA unwinding, and the mechanism by which these ligands can disturb genome integrity.

Plant molecular biology and biotechnology research in the post-recombinant DNA era

After the beginning of the recombinant DNA era in the mid-1970s, researchers in India started to make use of the new technology to understand the structure of plant genes and regulation of their expression. The outcome started to appear in print in early the 1980s and genes for histones, tubulin, photosynthetic membrane proteins, phototransduction components, organelles and those regulated differentially by developmental and extrinsic signals were sequenced and characterized. Some genes of biotechnological importance like those encoding an interesting seed protein and the enzyme glyoxalase were also isolated. While work on the characterization of genome structure and organization was started quite early, it remained largely focused on the identification of DNA markers and genetic variability. In this context, the work on mustard, rice and wheat is worth mentioning. In the year 2000, India became a member of the international consortium to sequence entire rice genome. Several laboratories have also given attention to regulated expression of plastid and nuclear genes as well as to isolate target-specific promoters or design promoters with improved potential. Simultaneously, transgenic systems for crops like mustard, rice, wheat, cotton, legumes and several vegetables have been established. More recently, genes of agronomic importance like those for insect resistance, abiotic stress tolerance, nutritional improvement and male sterility, isolated in India or abroad, have been utilized for raising transgenics for crop improvement. Some of these transgenics have already shown their potential in containment facility or limited field trials conducted under the stipulated guidelines. Plant molecular biology and biotechnology are thus clearly poised to make an impact on research in basic biology and agriculture in the near future.

A novel nuclear DNA helicase with high specific activity from Pisum sativum catalytically translocates in the 3'-->5' direction

A novel ATP-dependent nuclear DNA unwinding enzyme from pea has been purified to apparent homogeneity and characterized. This enzyme is present at extremely low abundance and has the highest specific activity among plant helicases. It is a heterodimer of 54 and 66 kDa polypeptides as determined by SDS/PAGE. On gel filtration chromatography and glycerol gradient centrifugation it gives a native molecular mass of 120 kDa and is named as pea DNA helicase 120 (PDH120). The enzyme can unwind 17-bp partial duplex substrates with equal efficiency whether or not they contain a fork. It translocates unidirectionally along the bound strand in the 3'-->5' direction. The enzyme also exhibits intrinsic single-stranded DNA- and Mg2+-dependent ATPase activity. ATP is the most favoured cofactor but other NTPs and dNTPs can also support the helicase activity with lower efficiency (ATP > GTP = dCTP > UTP > dTTP > CTP > dATP > dGTP) for which divalent cation (Mg2+ > Mn2+) is required. The DNA intercalating agents actinomycin C1, ethidium bromide, daunorubicin and nogalamycin inhibit the DNA unwinding activity of PDH120 with Ki values of 5.6, 5.2, 4.0 and 0.71 micro Ms, respectively. This inhibition might be due to the intercalation of the inhibitors into duplex DNA, which results in the formation of DNA-inhibitor complexes that impede the translocation of PDH120. Isolation of this new DNA helicase should make an important contribution to our better understanding of DNA transaction in plants.

Potent inhibition of DNA unwinding and ATPase activities of pea DNA helicase 45 by DNA-binding agents

Pea DNA helicase 45 (PDH45) is an ATP-dependent DNA unwinding enzyme, with intrinsic DNA-dependent ATPase activity [Plant J. 24 (2000) 219]. We have determined the effect of various DNA-binding agents, such as daunorubicin, ethidium bromide, ellipticine, cisplatin, nogalamycin, actinomycin C1, and camptothecin on the DNA unwinding and ATPase activities of the plant nuclear DNA helicase PDH45. The results show that all the agents except actinomycin C1, and camptothecin inhibited the helicase (apparent K(i) values ranging from 1.5 to 7.0 microM) and ATPase (apparent K(i) values ranging from 2.5 to 11.9 microM) activities. This is the first study to show the effect of various DNA-binding agents on the plant nuclear helicase and also first to demonstrate inhibition of any helicase by cisplatin. Another striking finding that the actinomycin C1 and ellipticine act differentially on PDH45 as compared to pea chloroplast helicase suggests that the mechanism of DNA unwinding could be different in nucleus and chloroplast. These results suggest that the intercalation of the inhibitors into duplex DNA generates a complex that impedes translocation of PDH45, resulting in both the inhibitions of unwinding activity and ATP hydrolysis. This study would be useful to obtain a better understanding of the mechanism of plant nuclear DNA helicase unwinding and the mechanism by which these agents can disturb genome integrity.

Unwinding of a DNA triple helix by the Werner and Bloom syndrome helicases

Bloom syndrome and Werner syndrome are genome instability disorders, which result from mutations in two different genes encoding helicases. Both enzymes are members of the RecQ family of helicases, have a 3' --> 5' polarity, and require a 3' single strand tail. In addition to their activity in unwinding duplex substrates, recent studies show that the two enzymes are able to unwind G2 and G4 tetraplexes, prompting speculation that failure to resolve these structures in Bloom syndrome and Werner syndrome cells may contribute to genome instability. The triple helix is another alternate DNA structure that can be formed by sequences that are widely distributed throughout the human genome. Here we show that purified Bloom and Werner helicases can unwind a DNA triple helix. The reactions are dependent on nucleoside triphosphate hydrolysis and require a free 3' tail attached to the third strand. The two enzymes unwound triplexes without requirement for a duplex extension that would form a fork at the junction of the tail and the triplex. In contrast, a duplex formed by the third strand and a complement to the triplex region was a poor substrate for both enzymes. However, the same duplex was readily unwound when a noncomplementary 5' tail was added to form a forked structure. It seems likely that structural features of the triplex mimic those of a fork and thus support efficient unwinding by the two helicases.

A pea homologue of human DNA helicase I is localized within the dense fibrillar component of the nucleolus and stimulated by phosphorylation with CK2 and cdc2 protein kinases

DNA helicases catalyse the transient opening of duplex DNA during nucleic acid transactions. Here we report the isolation of a second nuclear DNA helicase (65 kDa) from Pisum sativum (pea) designated pea DNA helicase 65 (PDH65). The enzyme was immunoaffinity purified using an antihuman DNA helicase I (HDH I) antibody column. The purified PDH65 showed ATP- and Mg(2+)-dependent DNA and RNA unwinding activities, as well as ssDNA-dependent ATPase activity. The direction of DNA unwinding was 3' to 5' along the bound strand. Antibodies against HDH I recognized the purified PDH65, and immunodepletion with these antibodies removed the DNA and RNA unwinding and ATPase activities from purified preparations of PDH65. The DNA and RNA unwinding activities were upregulated after phosphorylation of PDH65 with CK2 and cdc2 protein kinases. By incorporation of BrUTP into pea root tissue, followed by double immunofluorescence labelling and confocal microscopy, PDH65 was shown to be localized within the dense fibrillar component of pea root nucleoli in the regions around the rDNA transcription sites. These observations suggest that PDH65 may be involved both in rDNA transcription and in the early stages of pre-rRNA processing.

A DNA helicase from Pisum sativum is homologous to translation initiation factor and stimulates topoisomerase I activity

DNA helicases play an essential role in all aspects of nucleic acid metabolism, by providing a duplex-unwinding function. This is the first report of the isolation of a cDNA (1.6 kb) clone encoding functional DNA helicase from a plant (pea, Pisum sativum). The deduced amino-acid sequence has eight conserved helicase motifs of the DEAD-box protein family. It is a unique member of this family, containing DESD and SRT motifs instead of DEAD/H and SAT. The encoded 45.5 kDa protein has been overexpressed in bacteria and purified to homogeneity. The purified protein contains ATP-dependent DNA and RNA helicase, DNA-dependent ATPase, and ATP-binding activities. The protein sequence contains striking homology with eIF-4A, which has not so far been reported as DNA helicase. The antibodies against pea helicase inhibit in vitro translation. The gene is expressed as 1.6 kb mRNA in different organs of pea. The enzyme is localized in the nucleus and cytosol, and unwinds DNA in the 3' to 5' direction. The pea helicase interacts with pea topoisomerase I protein and stimulates its activity. These results suggest that pea DNA helicase could be an important multifunctional protein involved in protein synthesis, maintaining the basic activities of the cell, and in upregulation of topoisomerase I activity. The discovery of such a protein with intrinsic multiple activity should make an important contribution to our better understanding of DNA and RNA transactions in plants.