With the aid of an extracellular vibrating electrode, natural electric fields were detected and measured in the medium near growing roots and root hairs of barley seedlings. An exploration of these fields indicates that both the root as a whole, as well as individual root hairs, drive large steady currents through themselves. Current consistently enters both the main elongation zone of the root as weD as the growing tips of elongating root hairs; it leaves the surface of the root beneath the root hairs. These currents enter with a density of about 2 microamperes per square centimeter, leave with a density of about 0.5 to I microampere per square centimeter, and total about 30 nanoamperes.Responses of the natural fields to changes in the ionic composition of the medium as well as observations of the pH pattern in the medium near the roots (made with bromocresol purple) together indicate that much of the current consists of hydrogen ions. Altogether, H+ ions seem to leak into growing cells or ceD parts and to be pumped out of nongrowing ones.Natural electric currents seem to play a major role in the differentiation and growth of cells and tissues (8). For example, in the zygotes of the fucoid alga Pelvetia (9,17,23) and in the pollen grains of Lilium longiflorum (6, 32, 33), steady self-generated currents of about 1 ,uamp cm-2 (in zygotes) and up to 4 ,uamp cm-2 (in pollen grains) enter the sites of future or actual growth and leave the opposite, nongrowing parts of the cells. The ions that carry these natural currents are Na+, K+, Ca2+, and C1-in Pelvetia, and K+, Ca2+, and H+ in Lilium.If natural currents are an essential factor that controls cell differentiation and growth, currents should traverse other developing cells and tissues, too. To test this conclusion we have investigated the growing root hair and the root. Root hairs and roots were selected for three main reasons: (a) Root hairs take up water and salts from the soil and are therefore of great importance for the mineral nutrition of plants, a fact that calls for a better understanding of their development and growth. (b) Root hairs grow at their very tips; they therefore seem to need some mechanism to control this very localized growth, perhaps a self-generated current. (c) There are some older reports on natural electric fields around growing roots (25). We thought that it would be valuable to reinvestigate these natural electric fields with our small vibrating electrode and to link the fields to the flow of particular ions.
Atrial fibrillation (AF) is the most common cardiac arrhythmia, and the total number of AF patients is constantly increasing. The mechanisms leading to and sustaining AF are not completely understood yet. Heterogeneities in atrial electrophysiology seem to play an important role in this context. Although some heterogeneities have been used in in-silico human atrial modeling studies, they have not been thoroughly investigated. In this study, the original electrophysiological (EP) models of Courtemanche et al., Nygren et al. and Maleckar et al. were adjusted to reproduce action potentials in 13 atrial regions. The parameter sets were validated against experimental action potential duration data and ECG data from patients with AV block. The use of the heterogeneous EP model led to a more synchronized repolarization sequence in a variety of 3D atrial anatomical models. Combination of the heterogeneous EP model with a model of persistent AF-remodeled electrophysiology led to a drastic change in cell electrophysiology. Simulated Ta-waves were significantly shorter under the remodeling. The heterogeneities in cell electrophysiology explain the previously observed Ta-wave effects. The results mark an important step toward the reliable simulation of the atrial repolarization sequence, give a deeper understanding of the mechanism of atrial repolarization and enable further clinical investigations.
DNA-protein crosslinks (DPCs) represent a severe threat to the genome integrity; however, the main mechanisms of DPC repair were only recently elucidated in humans and yeast. Here we define the pathways for DPC repair in plants. Using CRISPR/Cas9, we could show that only one of two homologs of the universal repair proteases SPARTAN/ weak suppressor of smt3 (Wss1), WSS1A, is essential for DPC repair in Arabidopsis (Arabidopsis thaliana). WSS1A defective lines exhibit developmental defects and are hypersensitive to camptothecin (CPT) and cis-platin. Interestingly, the CRISPR/Cas9 mutants of TYROSYL-DNA PHOSPHODIESTERASE 1 (TDP1) are insensitive to CPT, and only the wss1A tdp1 double mutant reveals a higher sensitivity than the wss1A single mutant. This indicates that TDP1 defines a minor backup pathway in the repair of DPCs. Moreover, we found that knock out of the endonuclease METHYL METHANESULFONATE AND UV SENSITIVE PROTEIN 81 (MUS81) results in a strong sensitivity to DPC-inducing agents. The fact that wss1A mus81 and tdp1 mus81 double mutants exhibit growth defects and an increase in dead cells in root meristems after CPT treatment demonstrates that there are three independent pathways for DPC repair in Arabidopsis. These pathways are defined by their different biochemical specificities, as main actors, the DNA endonuclease MUS81 and the protease WSS1A, and the phosphodiesterase TDP1 as backup.
CRISPR/Cas is in the process of inducing the biggest transformation of plant breeding since the green revolution. Whereas initial efforts focused mainly on changing single traits by error prone non-homologous end joining, the last two years saw a tremendous technical progress achieving more complex genetic, epigenetic and transcriptional changes. The efficiencies of inducing directed changes by homologous recombination have been improved significantly and strategies to break genetic linkages by inducing chromosomal rearrangements have been developed. Cas13 systems have been applied to degrade viral and mRNA in plants. Most importantly, a historical breakthrough was accomplished: By introducing multiple genomic changes simultaneously, domestication of wild species in a single generation has been demonstrated, speeding up breeding dramatically.
Topoisomerase 3α, a class I topoisomerase, consists of a TOPRIM domain, an active centre and a variable number of zinc-finger domains (ZFDs) at the C-terminus, in multicellular organisms. Whereas the functions of the TOPRIM domain and the active centre are known, the specific role of the ZFDs is still obscure. In contrast to mammals where a knockout of TOP3α leads to lethality, we found that CRISPR/Cas induced mutants in Arabidopsis are viable but show growth retardation and meiotic defects, which can be reversed by the expression of the complete protein. However, complementation with AtTOP3α missing either the TOPRIM-domain or carrying a mutation of the catalytic tyrosine of the active centre leads to embryo lethality. Surprisingly, this phenotype can be overcome by the simultaneous removal of the ZFDs from the protein. In combination with a mutation of the nuclease AtMUS81, the TOP3α knockout proved to be also embryo lethal. Here, expression of TOP3α without ZFDs, and in particular without the conserved ZFD T1, leads to only a partly complementation in root growth—in contrast to the complete protein, that restores root length to mus81-1 mutant level. Expressing the E. coli resolvase RusA in this background, which is able to process Holliday junction (HJ)-like recombination intermediates, we could rescue this root growth defect. Considering all these results, we conclude that the ZFD T1 is specifically required for targeting the topoisomerase activity to HJ like recombination intermediates to enable their processing. In the case of an inactivated enzyme, this leads to cell death due to the masking of these intermediates, hindering their resolution by MUS81.
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