A conserved MADS-box phosphorylation motif regulates differentiation and mitochondrial function in skeletal, cardiac, and smooth muscle cells.

Exposure to metabolic disease during fetal development alters cellular differentiation and perturbs metabolic homeostasis, but the underlying molecular regulators of this phenomenon in muscle cells are not completely understood. To address this, we undertook a computational approach to identify cooperating partners of the myocyte enhancer factor-2 (MEF2) family of transcription factors, known regulators of muscle differentiation and metabolic function. We demonstrate that MEF2 and the serum response factor (SRF) collaboratively regulate the expression of numerous muscle-specific genes, including microRNA-133a (miR-133a). Using tandem mass spectrometry techniques, we identify a conserved phosphorylation motif within the MEF2 and SRF Mcm1 Agamous Deficiens SRF (MADS)-box that regulates miR-133a expression and mitochondrial function in response to a lipotoxic signal. Furthermore, reconstitution of MEF2 function by expression of a neutralizing mutation in this identified phosphorylation motif restores miR-133a expression and mitochondrial membrane potential during lipotoxicity. Mechanistically, we demonstrate that miR-133a regulates mitochondrial function through translational inhibition of a mitophagy and cell death modulating protein, called Nix. Finally, we show that rodents exposed to gestational diabetes during fetal development display muscle diacylglycerol accumulation, concurrent with insulin resistance, reduced miR-133a, and elevated Nix expression, as young adult rats. Given the diverse roles of miR-133a and Nix in regulating mitochondrial function, and proliferation in certain cancers, dysregulation of this genetic pathway may have broad implications involving insulin resistance, cardiovascular disease, and cancer biology.

A matrix attachment region is located upstream from the high-molecular-weight glutenin gene Bx7 in wheat (Triticum aestivum L.).

A 2.2-kb nucleotide sequence rich in AT, located upstream from the Bx7 allele of the high-molecular-weight glutenin Glu-B1 locus in wheat (Triticum aestivum cv. Glenlea) was cloned following amplification by PCR. The 5' region of this sequence contains motifs typically found in matrix attachment regions (MARs) in other plants. We have shown that part of the 2.2-kb DNA binds to wheat nuclear matrix (NM) in vitro, at least as strongly as a known MAR (Adh1) from maize suggesting that there is a MAR upstream of Bx7. This MAR is approximately 800 bases in length running from -750 to -1560 bases, relative to the start codon. Although the MAR is associated with a tissue-specific gene and is beside a strong tissue-specific promoter, the MAR sequence did not lead to tissue-specific expression of the beta-glucuronidase marker gene under the control of the rice actin promoter in various tissues. Presence of the MAR was only slightly beneficial with respect to expression levels, which were not greatly altered in transient expression assays in various wheat tissues although a slight increase in the number of foci was observed in leaves, which have low transformation efficiencies.

The complete nucleotide sequence of prune dwarf ilarvirus RNA-1.

The sequence of prune dwarf ilarvirus (PDV) RNA-1 has been determined; it consists of 3,374 nucleotides and contains a single open reading frame of 3,168 nucleotides. The putative translation product is 1,055 amino acids in length with a calculated molecular mass of 118.9 kDa. Both the nucleic acid and the translated amino acid sequences show stronger homology to the corresponding RNA-1 and ORF-1 of apple mosaic ilarvirus and alfalfa mosaic alfamovirus than to spinach latent mosaic ilarvirus or citrus leaf rugose ilarvirus. These findings are consistent with the inclusion of alfalfa mosaic virus in the ilarvirus genus. The reported sequence of PDV RNA-1 and its single ORF conform to the genomic organization typical of the Bromoviridae family.