Four hydrophobic amino acid residues in the C-terminal effector domain of the yeast Mig1p repressor are important for its in vivo activity

The Mig1 repressor is a zinc finger protein that mediates glucose repression in yeast. Previous work in Saccharomyces cerevisiae has shown that two domains in Mig1p are required for repression: the N-terminal zinc finger region and a C-terminal effector domain. Both domains are also conserved in Mig1p homologs from the distantly related yeasts Kluyveromyces lactis and K. marxianus, and these Mig1 proteins can fully replace the endogenous Mig1p in S. cerevisiae. We have now made a detailed analysis of the conserved C-terminal effector domain in Mig1p from K. marxianus, using expression in S. cerevisiae to monitor its function. First, a series of small deletions were made within the effector domain. Second, an alanine scan mutagenesis was carried out across the effector domain. Third, double, triple and quadruple mutants were made that affect certain residues within the effector domain. Our results show that four conserved residues within the effector domain, three leucines and one isoleucine, are particularly important for its function in vivo. The analysis further revealed that while the C-terminal effector domain of KmMig1p mediates a seven- to nine-fold repression of the reporter gene, a five- to sixfold residual effect also exists that is independent of the C-terminal effector domain. Similar results were obtained when the corresponding mutations were made in ScMig1p. Moreover, we found that mutations in these residues affect the interaction between Mig1p and the general corepressor subunit Cyc8p (Ssn6p). Modeling of the C-terminal effector domain using a protein of known structure suggests that it may be folded into an α-helix. Received: 30 March 1998 / Accepted: 18 August 1998     

Contrasting patterns of carbon sequestration between Gilbertiodendron dewevrei monodominant forests and Scorodophloeus zenkeri mixed forests in the Central Congo basin

Plant and Soil - Plant growth promoting rhizobacteria (PGPR) have been shown to reduce abiotic stress on plants, but these effects have not been quantitatively synthesized. We evaluated the degree...     

Cloning and Nucleotide Sequence of the Endoinulinase-Encoding Gene, inu2, from Aspergillus ficuum

A 2.3 kb DNA fragment that contains a gene encoding endoinulinase, inu2, from Aspergillus ficuum ATCC 16882 was isolated and analyzed. It includes an open reading frame of 1,551 bp, coding for a polypeptide with calculated molecular weight of 55,790 Da, including a putative signal peptide of 22 amino acids. Alignment of amino acid sequences revealed 73.3% identity and 93.9% similarity between A. ficuum and Penicillium purpurogenum endoinulinase.     

Functional traits drive the difference in soil respiration between Gilbertiodendron dewevrei monodominant forests patches and Scorodophloeus zenkeri mixed forests patches in the Central Congo basin.

Plant and Soil - In tropical rainforests, soil respiration accounts for the major part of ecosystem respiration, yet a deep understanding of the influence of forest type and species composition is...     

Altered mitochondrial oxidative phosphorylation capacity in horses suffering from polysaccharide storage myopathy

Polysaccharide storage myopathy (PSSM) is a widely described cause of exertional rhabdomyolysis in horses. Mitochondria play a central role in cellular energetics and are involved in human glycogen storage diseases but their role has been overlooked in equine PSSM. We hypothesized that the mitochondrial function is impaired in the myofibers of PSSM-affected horses. Nine horses with a history of recurrent exercise-associated rhabdomyolysis were tested for the glycogen synthase 1 gene (GYS1) mutation: 5 were tested positive (PSSM group) and 4 were tested negative (horses suffering from rhabdomyolysis of unknown origin, RUO group). Microbiopsies were collected from the gluteus medius (gm) and triceps brachii (tb) muscles of PSSM, RUO and healthy controls (HC) horses and used for histological analysis and for assessment of oxidative phosphorylation (OXPHOS) using high-resolution respirometry. The modification of mitochondrial respiration between HC, PSSM and RUO horses varied according to the muscle and to substrates feeding OXPHOS. In particular, compared to HC horses, the gm muscle of PSSM horses showed decreased OXPHOS- and electron transfer (ET)-capacities in presence of glutamate&malate&succinate. RUO horses showed a higher OXPHOS-capacity (with glutamate&malate) and ET-capacity (with glutamate&malate&succinate) in both muscles in comparison to the PSSM group. When expressed as ratios, our results highlighted a higher contribution of the NADH pathway (feeding electrons into Complex I) to maximal OXPHOS or ET-capacity in both rhabdomyolysis groups compared to the HC. Specific modifications in mitochondrial function might contribute to the pathogenesis of PSSM and of other types of exertional rhabdomyolyses.     

Comparative analysis in three fungi reveals structurally and functionally conserved regions in the Mig1 repressor

The Mig1 repressor is a key effector in glucose repression in the yeast Saccharomyces cerevisiae. To gain further insights into structure-function relationships, we have now cloned the MIG1 homologue from the yeast Kluyveromyces marxianus. The amino acid sequence deduced from KmMIG1 differs significantly from ScMig1p outside the highly conserved zinc fingers. However, 12 discrete conserved motifs could be identified in a multiple alignment that also included the K. lactis Mig1p sequence. We further found that KmMig1p is fully functional when expressed in S. cerevisiae. First, it represses the SUC2 promoter almost as well as ScMig1p. This repression requires the Cyc8 and Tup1 proteins and is dependent on a C-terminal region comprising several conserved leucine-proline repeats. Second, KmMig1p is regulated by glucose in S. cerevisiae, and a KmMig1-VP16 hybrid activator is inhibited by the ScSnf1p kinase in the absence of glucose. This suggests that KmMig1p has retained the ability to interact with several S. cerevisiae proteins, and reinforces the notion that the conserved motifs are functionally important. Finally, we found that the physiological role of Mig1p also is conserved in K. marxianus, since KmMig1p represses INU1, the counterpart of SUC2 in this organism. Received: 16 October 1996 / Accepted: 19 February 1997     

Three-dimensional reconstruction of human diaphragm with the use of spiral computed tomography

Pettiaux, Nicolas, Marie Cassart, Manuel Paiva, and MarcEstenne. Three-dimensional reconstruction of human diaphragm withthe use of spiral computed tomography. J. Appl.Physiol. 82(3): 998-1002, 1997.We developed atechnique of diaphragm imaging by using spiral computed tomography, andwe studied four normal subjects who had been previously investigatedwith magnetic resonance imaging (A. P. Gauthier, S. Verbanck,M. Estenne, C. Segebarth, P. T. Macklem, and M. Paiva.J. Appl. Physiol. 76: 495-506,1994). One acquisition of 15- to 25-s duration was performed atresidual volume, functional residual capacity, functional residualcapacity plus one-half inspiratory capacity, and total lung capacitywith the subject holding his breath and relaxing. From theseacquisitions, 20 coronal and 30 sagittal images were reconstructed ateach lung volume; on each image, diaphragm contour in the zone ofapposition and in the dome was digitized with the software Osiris, andthe digitized silhouettes were used for three-dimensionalreconstruction with Matlab. Values of length and surface area for thediaphragm, the dome, and the zone of apposition were very similar tothose obtained with magnetic resonance imaging. We conclude thatsatisfactory three-dimensional reconstruction of the in vivo diaphragmmay be obtained with spiral computed tomography, allowing accurate measurements of muscle length, surface area, and shape.

     

Cloning and sequencing of the inulinase gene of Kluyveromyces marxianus var. marxianus ATCC 12424.

Cell wall inulinase (EC 3.2.1.7) was purified from Kluyveromyces marxianus var. marxianus (formerly K. fragilis) and its N-terminal 33-amino acid sequence was established. PCR amplification of cDNA with 2 sets of degenerate primers yielded a genomic probe which was then used to screen a genomic library established in the YEp351 yeast shuttle vector. One of the selected recombinant plasmids allowed an invertase-negative Saccharomyces cerevisiae mutant to grow on inulin. It was shown to contain an inulinase gene (INU 1) encoding a 555-amino acid precursor protein with a typical N-terminal signal peptide. The sequence of inulinase displays a high similarity (67%) to S. cerevisiae invertase, suggesting a common evolutionary origin for yeast beta-fructosidases with different substrate preferences.