Desiccation and cryopreservation of actively-growing cultured plant cells and protoplasts

Actively-growing cultured cells of Pogonatum and Polytrichum were desiccated and cryopreserved. Although Pogonatum was slightly more tolerant to desiccation, both species were cryopreserved with >90% survival rate. An examination of isolated protoplasts revealed that differences in desiccation tolerance were likely dependent on levels of injury of plasma membranes. Trehalose and sucrose provided some protective effects during protoplast desiccation, but mannitol and glucose were less effective when Pogonatum protoplasts were directly desiccated and preserved at various temperatures. The effectiveness of glucose was enhanced when combined with culture medium components.     

Novel Toxin-Antitoxin System Composed of Serine Protease and AAA-ATPase Homologues Determines the High Level of Stability and Incompatibility of the Tumor-Inducing Plasmid pTiC58

Stability of plant tumor-inducing (Ti) plasmids differs among strains. A high level of stability prevents basic and applied studies including the development of useful strains. The nopaline type Ti plasmid pTiC58 significantly reduces the transconjugant efficiency for incoming incompatible plasmids relative to the other type, such as octopine-type plasmids. In this study we identified a region that increases the incompatibility and stability of the plasmid. This region was located on a 4.3-kbp segment about 38 kbp downstream of the replication locus, repABC. We named two open reading frames in the segment, ietA and ietS, both of which were essential for the high level of incompatibility and stability. Plasmid stabilization by ietAS was accomplished by a toxin-antitoxin (TA) mechanism, where IetS is the toxin and IetA is the antitoxin. A database search revealed that putative IetA and IetS proteins are highly similar to AAA-ATPases and subtilisin-like serine proteases, respectively. Amino acid substitution experiments in each of the highly conserved characteristic residues, in both putative enzymes, suggested that the protease activity is essential and that ATP binding activity is important for the operation of the TA system. The ietAS-containing repABC plasmids expelled Ti plasmids even in strains which were tolerant to conventional Ti-curing treatments.Agrobacterium tumefaciens strains bearing a tumor-inducing (Ti) plasmid are the etiological agents of crown gall disease. Most genes required for pathogenicity are located on the plasmids (17, 33). Ti plasmids are kept stable at a low copy number equivalent to that of the chromosomal DNA in the bacterial cells (32) due to the repABC locus (16, 30, 34). The stability of Ti plasmids differs among strains (11).Many genes for keeping plasmids stable have been reported in eubacteria, and these are divided into three categories based on their mechanism: multimer resolution systems, active partitioning systems, and toxin-antitoxin (TA) systems (15). Multimer resolution systems increase the number of plasmid molecules by resolving a multimer plasmid into monomers, resulting in a higher probability of plasmid distribution to daughter cells during cell division even when plasmid distribution occurs randomly (29). Active partitioning systems deliver plasmid copies to each progeny cell at cell division (21). In the repABC locus, the RepA and RepB proteins and parS site(s) ensure stable plasmid inheritance by the active partitioning system (2). TA systems contribute to plasmid maintenance in cell populations by initiating growth inhibition or death of plasmid-free cells and are widely distributed among eubacterial and archaeal plasmids as well as their chromosomes (9). Generally, the TA module consists of two genes which encode toxin and antitoxin. The antitoxin neutralizes the action of a cognate toxin by interaction with the toxin or its target molecules. When a plasmid harboring the TA module is lost from a host cell, the antitoxin molecules decrease to an ineffective level because the antitoxin is degraded quickly or diluted by cell division (15). Thereafter, the toxin exerts its toxicity and inhibits the host cell growth. RNA antitoxins can suppress toxin expression by binding to the toxin mRNA as an antisense RNA or repress toxicity effects by an unknown mechanism (6, 4). In pTi-SAKURA, the Ti plasmid in the A. tumefaciens strain MAFF301001, it was shown that the tiorf24 and tiorf25 module increased plasmid stability by the TA mechanism (40; also S. Yamamoto, unpublished data).Differences in Ti plasmid stability are critical for plasmid engineering and evolution (33). However, little is known about the stability factors of Ti plasmids other than the repABC locus. In our previous study (40), tiorf24 and tiorf25 were shown to increase the segregational stability and incompatibility of Ti plasmids and reduce the efficiency of transconjugants by the introduction of incompatible plasmids into host cells. The two genes are located 2.5-kbp downstream of repABC (8). Generally, incompatibility has been defined as a situation where two plasmids contain a related replication and/or partitioning system and are unable to exist in a cell simultaneously without external selection (1). A. tumefaciens strain C58, which contains a Ti plasmid pTiC58, allows entry of an incompatible repABC plasmid into the cell 60-fold less efficiently than a derivative of C58. The derivative of C58 harbors a small repABC vector instead of pTiC58 (40). This suggests the presence of incompatibility-enhancing genes on pTiC58.In this study, we located the responsible genes in pTiC58 and found that the novel genes ietA and ietS enhance the incompatibility and stability of the plasmid by the TA mechanism.     

Novel modulators for body weight changes induced by fasting and re-feeding in mice

Catch-up weight gain after malnutrition is a risk factor for metabolic syndrome. Here we show that social isolation enhanced fasting-induced weight loss and suppressed weight gain induced by re-feeding for 6 days following a 24-h fast in prepubertal wild-type mice. These effects of social isolation on weight gain were not associated with significant changes in daily average food consumption. Under the same housing condition, genetic deletion of β-endorphin reduced the fasting-induced weight loss and enhanced the re-feeding-induced weight gain in prepubertal mice. These effects of social isolation or genetic deletion of β-endorphin on these weight changes were attenuated and reversed in postpubertal mice. Moreover, genetic deletion of β-endorphin attenuated these effects of social isolation on the catch-up weight gain in prepubertal mice and reversed them in postpubertal mice. Thus, social isolation, endogenous β-endorphin, and age can be novel modulators for body weight changes induced by fasting and re-feeding in mice.     

Expression of the peroxisome proliferator activated receptor γ gene is repressed by DNA methylation in visceral adipose tissue of mouse models of diabetes

Background  

Adipose tissues serve not only as a store for energy in the form of lipid, but also as endocrine tissues that regulates metabolic activities of the organism by secreting various kinds of hormones. Peroxisome proliferator activated receptor γ (PPARγ) is a key regulator of adipocyte differentiation that induces the expression of adipocyte-specific genes in preadipocytes and mediates their differentiation into adipocytes. Furthermore, PPARγ has an important role to maintain the physiological function of mature adipocyte by controlling expressions of various genes properly. Therefore, any reduction in amount and activity of PPARγ is linked to the pathogenesis of metabolic syndrome.     

Comprehensive phenotypic analysis for identification of genes affecting growth under ethanol stress in Saccharomyces cerevisiae

We quantified the growth behavior of all available single gene deletion strains of budding yeast under ethanol stress. Genome-wide analyses enabled the extraction of the genes and determination of the functional categories required for growth under this condition. Statistical analyses revealed that the growth of 446 deletion strains under stress induced by 8% ethanol was defective. We classified these deleted genes into known functional categories, and found that many were important for growth under ethanol stress including several categories that have not been characterized, such as peroxisome. We also performed genome-wide screening under osmotic stress and identified 329 osmotic-sensitive strains. We excluded these strains from the 446 ethanol-sensitive strains to extract the genes whose deletion caused sensitivity to ethanol-specific (359 genes), osmotic-specific (242 genes), and both stresses (87 genes). We also extracted the functional categories that are specifically important for growth under ethanol stress. The genes and functional categories identified in the analysis might provide clues to improving ethanol stress tolerance among yeast cells.     

Causes of Abnormal Ca2+ Transients in Guinea Pig Pathophysiological Ventricular Muscle Revealed by Ca2+ and Action Potential Imaging at Cellular Level

Background

Abnormal Ca²⁺ transients are often observed in heart muscles under a variety of pathophysiological conditions including ventricular tachycardia. To clarify whether these abnormal Ca²⁺ transients can be attributed to abnormal action potential generation or abnormal Ca²⁺ handling/excitation-contraction (EC) coupling, we developed a procedure to determine Ca²⁺ and action potential signals at the cellular level in isolated heart tissues.

Methodology/Principal Findings

After loading ventricular papillary muscle with rhod-2 and di-4-ANEPPS, mono-wavelength fluorescence images from rhod-2 and ratiometric images of two wavelengths of emission from di-4-ANEPPS were sequentially obtained. To mimic the ventricular tachycardia, the ventricular muscles were field-stimulated in non-flowing Krebs solution which elicited abnormal Ca²⁺ transients. For the failed and alternating Ca²⁺ transient generation, there were two types of causes, i.e., failed or abnormal action potential generation and abnormal EC coupling. In cells showing delayed initiation of Ca²⁺ transients with field stimulation, action potential onset was delayed and the rate of rise was slower than in healthy cells. Similar delayed onset was also observed in the presence of heptanol, an inhibitor of gap junction channels but having a non-specific channel blocking effect. A Na⁺ channel blocker, on the other hand, reduced the rate of rise of the action potentials but did not result in desynchronization of the action potentials. The delayed onset of action potentials can be explained primarily by impaired gap junctions and partly by Na⁺ channel inactivation.

Conclusions/Significance

Our results indicate that there are multiple patterns for the causes of abnormal Ca²⁺ signals and that our methods are useful for investigating the physiology and pathophysiology of heart muscle.     

ATR homolog Mec1 controls association of DNA polymerase zeta-Rev1 complex with regions near a double-strand break

DNA polymerase zeta (Polzeta) and Rev1 contribute to the bypassing of DNA lesions, termed translesion DNA synthesis (TLS). Polzeta consists of two subunits, one encoded by REV3 (the catalytic subunit) and the other encoded by REV7. Rev1 acts as a deoxycytidyl transferase, inserting dCMP opposite lesions. Polzeta and Rev1 have been shown to operate in the same TLS pathway in the budding yeast Saccharomyces cerevisiae. Here, we show that budding yeast Polzeta and Rev1 form a complex and associate together with double-strand breaks (DSBs). As a component of the Polzeta-Rev1 complex, Rev1 plays a noncatalytic role in the association with DSBs. In budding yeast, the ATR-homolog Mec1 plays a central role in the DNA-damage checkpoint response. We further show that Mec1-dependent phosphorylation promotes the Polzeta-Rev1 association with DSBs. Rev1 association with DSBs requires neither the function of the Rad24 checkpoint-clamp loader nor the Rad6-Rad18-mediated ubiquitination of PCNA. Our results reveal a novel role of Mec1 in the localization of the Polzeta-Rev1 complex to DNA lesions and highlight a linkage of TLS polymerases to the checkpoint response.     

Marine Biodiversity in Japanese Waters

To understand marine biodiversity in Japanese waters, we have compiled information on the marine biota in Japanese waters, including the number of described species (species richness), the history of marine biology research in Japan, the state of knowledge, the number of endemic species, the number of identified but undescribed species, the number of known introduced species, and the number of taxonomic experts and identification guides, with consideration of the general ocean environmental background, such as the physical and geological settings. A total of 33,629 species have been reported to occur in Japanese waters. The state of knowledge was extremely variable, with taxa containing many inconspicuous, smaller species tending to be less well known. The total number of identified but undescribed species was at least 121,913. The total number of described species combined with the number of identified but undescribed species reached 155,542. This is the best estimate of the total number of species in Japanese waters and indicates that more than 70% of Japan''s marine biodiversity remains un-described. The number of species reported as introduced into Japanese waters was 39. This is the first attempt to estimate species richness for all marine species in Japanese waters. Although its marine biota can be considered relatively well known, at least within the Asian-Pacific region, considering the vast number of different marine environments such as coral reefs, ocean trenches, ice-bound waters, methane seeps, and hydrothermal vents, much work remains to be done. We expect global change to have a tremendous impact on marine biodiversity and ecosystems. Japan is in a particularly suitable geographic situation and has a lot of facilities for conducting marine science research. Japan has an important responsibility to contribute to our understanding of life in the oceans.