Three different DNA polymerase activities can be resolved by passing a protein extract from 24 h imbibed maize axes through DEAE-cellulose. These activities have been numbered 1, 2 and 3, according to their elution order. One of them, DNA polymerase 2, elutes at 100-120 mM phosphates. This enzyme was further purified by passing it through Heparin-Sepharose, Sephacryl S-300 and DNA cellulose. Purification was nearly 5000-fold. The enzyme needs Mg2+, is stimulated by K+, has an optimum pH of 7.0 and its optimum temperature is 30-37 degrees C. Specific inhibitors for different types of polymerases, such as aphidicolin, dideoxythymidine triphosphate and N-ethyl maleimide, gave intermediate values of inhibition, making impossible the definition of the type of enzyme purified by its inhibitory pattern. SDS-PAGE indicated the presence of several bands of molecular masses of 28-40, 56 and 15 kDa. Most of these bands could be visualized when proteins from crude extracts were analyzed by western blot, using an antibody against calf thymus DNA polymerase alpha. A high molecular mass (around 500 kDa) was calculated by western blot of native gels using the same antibody. Finally, specific activity of this enzyme increased 100-fold during maize germination whereas polymerase 3 virtually did not increase. Furthermore, immunoprecipitation experiments with the antipolymerase alpha-antibody showed a decrease in DNA polymerase activity by 70%. The possibility that polymerase 2 is a replicative enzyme is discussed.
Cyclin proteins, associated to cyclin-dependent kinases (CDKs), play fundamental roles in cell cycle control as they constitute a very important driving force to allow cell cycle progression. D-type cyclins (CycDs) are important both for interpreting external mitogenic signals and in the control of the G1 phase. The maize (Zea mays) genome appears to contain at least 17 different CycD genes, and they fall into the subgroups previously described for other plants. Maize CycDs have been named according to identity percentages of the corresponding orthologs in rice and Arabidopsis. In silico analysis confirmed the presence of characteristic cyclin domains in each maize CycD gene and showed that their genomic organization is similar to their orthologs in rice and Arabidopsis. The expression of maize CycD genes was followed in seeds, during germination in the presence/absence of exogenously added hormones, and also in different plantlet tissues (mesocotyl, root tips and first leaf). Most cyclins were expressed in germinating seeds and at least in one of the plantlet tissues tested; almost all of the detected cyclins show an accumulating pattern of mRNA along germination (0-24 h) and higher levels in root tissue. Interestingly, some cyclins show high levels in non-proliferating tissues as leaf. Addition of auxins or cytokinins does not seem to importantly modify transcript levels; on the other hand, addition of abscisic acid repressed the expression of several cyclins. The role of each CycD during germination and plant growth and its interaction with other cell cycle proteins becomes a topic of the highest interest.
The importance of cell proliferation in plant growth and development has been well documented. The majority of studies on basic cell cycle mechanisms in plants have been at the level of gene expression and much less knowledge has accumulated in terms of protein interactions and activation. Two key proteins, cyclins and cyclin-dependent kinases (CDKs) are fundamental for cell cycle regulation and advancement. Our aim has been to understand the role of D-type cyclins and type A and B CDKs in the cell cycle taking place during a developmental process such as maize seed germination. Results indicate that three maize D-type cyclins—D2;2, D4;2, and D5;3—(G1-S cyclins by definition) bind and activate two different types of CDK—A and B1;1—in a differential way during germination. Whereas CDKA–D-type cyclin complexes are more active at early germination times than at later times, it was surprising to observe that CDKB1;1, a supposedly G2-M kinase, bound in a differential way to all D-type cyclins tested during germination. Binding to cyclin D2;2 was detectable at all germination times, forming a complex with kinase activity, whereas binding to D4;2 and D5;3 was more variable; in particular, D5;3 was only detected at late germination times. Results are discussed in terms of cell cycle advancement and its importance for seed germination.
Octopus maya is a major socio-economic resource from the Yucatán Peninsula in Mexico. In this study we report for the first time the chemical composition of the saliva of O. maya and its effect on natural prey, i.e. the blue crab (Callinectes sapidus), the crown conch snail (Melongena corona bispinosa), as well as conspecifics. Salivary posterior glands were collected from octopus caught by local fishers and extracted with water; this extract paralyzed and predigested crabs when it was injected into the third pereiopod. The water extract was fractionated by membrane ultrafiltration with a molecular weight cut-off of 3kDa leading to a metabolic phase (>3kDa) and a neurotoxic fraction (<3kDa). The neurotoxic fraction injected in the crabs caused paralysis and postural changes. Crabs recovered to their initial condition within two hours, which suggests that the effects of the neurotoxic fraction were reversible. The neurotoxic fraction was also active on O. maya conspecifics, partly paralyzing and sedating them; this suggests that octopus saliva might be used among conspecifics for defense and for reduction of competition. Bioguided separation of the neurotoxic fraction by chromatography led to a paralysis fraction and a relaxing fraction. The paralyzing activity of the saliva was exerted by amino acids, while the relaxing activity was due to the presence of serotonin. Prey-handling studies revealed that O. maya punctures the eye or arthrodial membrane when predating blue crabs and uses the radula to bore through crown conch shells; these differing strategies may help O. maya to reduce the time needed to handle its prey.
We have cloned a 1563-bp cDNA sequence from a reported 2072-bp cDNA (including a fragment of the 3 0 UTR region, accession number AY109773) corresponding to the carboxy half of maize DNA polymerase d [Zea mays delta-type DNA polymerase catalytic subunit (Zmpold); EC 2.7.7.7], and its sequence shows an identity of 95, 77 and 74% to rice, soybean and Arabidopsis enzymes, respectively, although identity is even higher if only the pold-defining domain sequences are considered. An important difference between the monocot and dicot enzymes is the presence in the former of Zn fingers apparently required for binding to the DNA pold holoenzyme B subunit, which is absent in the dicot enzymes. Expression of Zmpold and protein levels during germination remain unchanged; however, pold shows two peaks of activity, one during early germination, perhaps related to DNA repair processes and a second peak when DNA replication is already in progress, indicating that Zmpold is regulated at the post-translational level. Zmpold has been found mainly in proliferative tissues in seeds and plantlets, although surprisingly, it is also present in seed endosperm, together with Zm proliferating cell nuclear antigen.
DNA polymerase and DNA primase activities in the maize alpha-type DNA polymerase 2 were dissociated and DNA polymerase-free DNA primase was studied. DNA primase synthesized primers that were 8-34 nucleotides long, with more intense bands at 15-17 nucleotides in length. DNA polymerase 1 (a putative delta-type enzyme) or DNA polymerase 2 were assayed after template-priming with purified DNA primase and showed a differential use of templates: whereas DNA polymerase 2 used a polydT template more efficiently than a natural template, DNA polymerase 1 used both of them poorly. The molecular size of DNA primase was estimated to be 68 kDa by gel filtration, western blotting and by a DNA primase 'trapping' assay.
Plant KRP proteins are cyclin/cyclin-dependent kinase subunit (Cdk) inhibitors that share a limited homology with mammalian p27 Kip1 proteins. Several KRPs have been reported in maize (Zea mays L.), of which Zeama;KRP1 was studied during maize germination. Expression of the Zeama;KRP1 gene did not vary during the 24 h germination period. A homologous antibody raised against the 13 kDa carboxy end of the Zeama;KRP1 polypeptide, a sequence containing the cyclin/Cdk inhibitory domain, indicated the existence of a 22 kDa protein in maize embryonic axes, the amount of which also remained unchanged during germination. Neither abscisic acid nor cytokinins modified the amount of protein. The purified Zeama;KRP1 polypeptide inhibited the kinase activity associated with Zeama;PCNA and Zeama;CycD2;1, and also the kinase activity in p13 Suc1 -pulled-down complexes. However, there were differences in the inhibition pattern during germination. Whereas kinase activity in proliferating cell nuclear antigen (PCNA) or CycD2;1 immunoprecipitates was strongly inhibited mainly during early germination, that in p13 Suc1pulled-down complexes was mainly inhibited at late times, suggesting that each protein complex is composed of different cyclins and/or Cdks.
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