Expression of the genes encoding RhtB family proteins depends on global regulator Lrp

In the present work, further study of the genes encoding RhtB family proteins is presented. In our previous work the involvement of two family members, RhtB and RhtC, in efflux of amino acids was demonstrated. Now we investigated regulation of expression of the rhtB, rhtC, yeaS and yahN genes. It is shown that expression of these genes is under control of the global regulator Lrp, depends on the presence of some amino acids in growth medium, and increases during different physiological stresses.     

Rapid reprogramming of globin gene expression in transient heterokaryons

Interspecific heterokaryons were formed by fusing adult mouse erythroleukemia (MEL) cells and human embryonic/fetal erythroid (K562) cells with each other, or with a variety of mouse and human nonerythroid cell types. Analysis of total cellular RNA isolated 24 hr after fusion revealed that normally inactive globin genes can be activated in these "transient" heterokaryons, in which the nuclei do not fuse. In general, the types of globin genes expressed in the donor erythroid cell are activated in the nucleus of the recipient cell. Therefore, erythroid cells contain transacting regulatory factors that are capable of activating the expression of globin genes in a stage- and tissue-specific manner. These observations also indicate that globin genes are not irreversibly repressed in differentiated cells and that their expression can be rapidly reprogrammed in the presence of the appropriate regulatory factors.     

Expression of lysosomal enzymes in human mutant fibroblast-chick erythrocyte heterokaryons

The generation of enzymes located in lysosomes, in cytosol or in endoplasmatic reticulum/Golgi complex is studied in heterokaryons in which chick erythrocyte nuclei are reactivated. The lysosomal enzymes, alpha-glucosidase (alpha-glu) and beta-galactosidase (beta-gal), are synthesized in heterokaryons obtained after fusion of chick erythrocytes with human fibroblasts of patients with Pompe's disease (alpha-glu-deficient) and GM1-gangliosidosis (beta-gal-deficient), respectively. The enzymes appear to be of chick origin and their activities can be detected at first around 4 days after fusion, i.e., at a time when the nucleoli in the erythrocyte nuclei have been reactivated. Maximal activities are reached around 15 days after fusion. No generation of the lysosomal enzyme beta-hexosaminidase is detected in the heterokaryons up to 23 days after fusion of chick erythrocyte with either beta-hexosaminidase A- and B-deficient fibroblasts (Sandhoff's disease) or beta-hexosaminidase A-deficient fibroblasts (Tay-Sachs disease). Similarly no expression of the cytosol enzyme glucose-6-phosphate dehydrogenase (G6PD) is fond up to 30 days after fusion, when chick erythrocytes are fused with fibroblasts from two different G6PD-deficient cell strains (residual activities of 4 and 20% respectively). Indirectly we examined N-acetyl-glucosamine-1-phosphate transferase activity, an enzyme located in the endoplasmic reticulum/Golgi region. This enzyme is needed for the phosphorylation of the lysosomal hydrolases and absence of its activity is the cause of the multiple lysosomal enzyme deficiencies in patients with I-cell disease. The retention of both, chick and human beta-galactosidase in the experiments in which I-cell fibroblasts were fused with chick erythrocytes indicates a reactivation of the gene coding for this phosphorylating enzyme. It also implies that this step in the processing of human lysosomal enzymes is not species-specific.     

Pattern of chick gene activation in chick erythrocyte heterokaryons

The reactivation of chicken erythrocyte nuclei in chick-mammalian heterokaryons resulted in the activation of chick globin gene expression. However, the level of chick globin synthesis was dependent on the mammalian parental cell type. The level of globin synthesis was high in chick erythrocyte-rat L6 myoblast heterokaryons but was 10-fold lower in chick erythrocyte-mouse A9 cell heterokaryons. Heterokaryons between chick erythrocytes and a hybrid cell line between L6 and A9 expressed chick globin at a level similar to that of A9 heterokaryons. Erythrocyte nuclei reactivated in murine NA neuroblastoma, 3T3, BHK and NRK cells, or in chicken fibroblasts expressed less than 5% chick globin compared with the chick erythrocyte-L6 myoblast heterokaryons. The amount of globin expressed in heterokaryons correlated with globin mRNA levels. Hemin increased beta globin synthesis two- to threefold in chick erythrocyte-NA neuroblastoma heterokaryons; however, total globin synthesis was still less than 10% that of L6 heterokaryons. Distinct from the variability in globin expression, chick erythrocyte heterokaryons synthesized chick constitutive polypeptides in similar amounts independent of the mammalian parental cell type. Approximately 40 constitutive chick polypeptides were detected in heterokaryons after immunopurification and two-dimensional gel electrophoresis. The pattern of synthesis of these polypeptides was similar in heterokaryons formed by fusing chicken erythrocytes with rat L6 myoblasts, hamster BHK cells, or mouse neuroblastoma cells. Three polypeptides synthesized by non-erythroid chicken cells but less so by embryonic erythrocytes were conspicuous in heterokaryons. Two abundant erythrocyte polypeptides were insignificant in non-erythroid chicken cells and in heterokaryons.     

Expression of a yeast glycolytic gene is subject to dosage limitation

The Saccharomyces cerevisiae pyruvate kinase-encoding gene (PYK1) has been transformed back into yeast using a derivative of the multicopy vector, pJDB207. High levels of PYK1 expression in these transformants are limited by at least two separate mechanisms. Pyruvate kinase assays and polysome analyses demonstrate that the translation of the PYK1 mRNA is inhibited as its abundance increases. The abundance of the PYK1 mRNA per gene copy also decreases as the copy number of the PYK1 gene increases. This is the first report which demonstrates that a eukaryotic glycolytic gene is subject to dosage limitation at the translational level.     

Circadian time-place learning in mice depends on Cry genes

Endogenous biological clocks allow organisms to anticipate daily environmental cycles. The ability to achieve time-place associations is key to the survival and reproductive success of animals. The ability to link the location of a stimulus (usually food) with time of day has been coined time-place learning, but its circadian nature was only shown in honeybees and birds. So far, an unambiguous circadian time-place-learning paradigm for mammals is lacking. We studied whether expression of the clock gene Cryptochrome (Cry), crucial for circadian timing, is a prerequisite for time-place learning. Time-place learning in mice was achieved by developing a novel paradigm in which food reward at specific times of day was counterbalanced by the penalty of receiving a mild footshock. Mice lacking the core clock genes Cry1 and Cry2 (Cry double knockout mice; Cry1(-/-)Cry2(-/-)) learned to avoid unpleasant sensory experiences (mild footshock) and could locate a food reward in a spatial learning task (place preference). These mice failed, however, to learn time-place associations. This specific learning and memory deficit shows that a Cry-gene dependent circadian timing system underlies the utilization of time of day information. These results reveal a new functional role of the mammalian circadian timing system.     

Force variability depends on core and muscle temperature

The aim of this study was to investigate if voluntary activation and force variability during maximal voluntary contraction (MVC) depends more on muscle (local) or body (core) temperature. Ten volunteers performed a 2-min MVC of the knee extensors under the control (CON) conditions (ambient temperature (21 °C), relative humidity (30%), and air velocity (∼0.1 m/s)) as well as after heating (HT) and cooling (CL) of the lower body. During water manipulation procedure lower body was immersed up to the waist in a water bath at ∼44 °C for 45 min for HT experiment, and ∼15 °C for 30 min for CL experiment. Peak torque, torque variability, muscle voluntary activation and half-relaxation time were assessed during the exercise. HT increased muscle (2.8±0.2 °C) and rectal (1.9±0.1 °C) temperatures while CL lowered muscle (2.2±0.2 °C) temperature, but did not affect rectal temperature. During 2-min MVC, peak torque decreased (P<0.05; SP>90%) and to a lower level in HT compared to CON and CL experiments (52.6±2.3% versus 69.0±2.3% and 65.6±1.9% MVC, respectively, P<0.05; SP>90%). Torque variability increased significantly during exercise and was significantly larger in HT and lower in CL compared to CON experiment. Voluntary activation of exercising muscle was more depressed in HT (i.e. greater central fatigue) and the smallest effect was found in CL compared to CON. In conclusion increased core and muscle temperature impairs voluntary activation and increases force variability of the exercising muscles while a local muscle cooling decrease force variability but has a small effect on central fatigue.     

Horizontal gene transfer depends on gene content of the host

Horizontal gene transfer is a major contributor to the evolution of bacterial genomes. We examine this process through a combination of comparative genomics and in silico analysis of the Escherichia coli metabolic network. We validate our horizontal transfer estimates by confirming the predicted gradual amelioration of GC content over time. We find that the chance of acquiring a gene by horizontal transfer is up to six times higher if an enzyme that catalyses a coupled metabolite flux is already encoded in the host genome.     

Cell cycle progression during endosperm development in Zea mays depends on parental dosage effects

Interploidy crosses in flowering plants often cause seed abortion. Studies in maize have shown that failure of kernel development results from dosage effects among products of imprinted but as-yet-unknown genes in the endosperm, and that the operative stoichiometry is established for a ratio of two maternal genomes to one paternal genome. In this study, we used flow cytometry to monitor cell cycle activities in developing endosperms obtained after reciprocal crosses between diploid and tetraploid maize individuals. Our data show that dosage effects alter critical events involved in the establishment of endoreduplication during maize endosperm development. Particularly, maternal genomic excess (4x x 2x crosses) forces endosperm cells to enter early into endoreduplication while paternal genomic excess (2x x 4x crosses) prevents its establishment. Our results also suggest that altering mechanisms depend on two different sets of cell cycle regulatory genes--one imprinted through the female that is required for mitotic arrest, and another responsible for re-entry into S phase that is imprinted through the male. Further, molecular and physiological analyses should provide insights into the interaction of parental imprinting action and cell cycle regulation during endosperm development.