Repellents of the maize pathogen Ustilago maydis are involved in formation of hydrophobic aerial hyphae and in cellular attachment. These peptides, called Rep1-1 to Rep1-11, are encoded by the rep1 gene and result from cleavage of the precursor protein Rep1 during passage of the secretion pathway. Using green fluorescent protein as a reporter, we here show that rep1 is expressed in filaments and not in the yeast form of U. maydis. In situ hybridization localized rep1 mRNA in the apex of the filament, which correlates with the expected site of secretion of the repellents into the cell wall. We also produced a synthetic peptide, Rep1-1. This peptide reduced the water surface tension to as low as 36 mJ m ؊2 . In addition, it formed amyloid-like fibrils as was shown by negative staining, by thioflavin T fluorescence, and by x-ray diffraction. These fibrils were not soluble in SDS but could be dissociated with trifluoroacetic acid. The repellents in the hyphal cell wall had a similar solubility and also stained with thioflavin T, strongly indicating that they are present as amyloid fibrils. However, such fibrils could not be observed at the hyphal surface. This can be explained by the fact that the Rep1-1 filaments decrease in length at increasing concentrations. Taken together, we have identified the second class of fungal proteins that form functional amyloid-like filaments at the hyphal surface.Ustilago maydis is the causal agent of smut in Zea mays (maize) and Euchlaena mexicana (Mexican teosinte). A filamentous pathogenic dikaryon is formed upon fusion of compatible yeast-like sporidia. Differentiation in the plant leads to the formation of diploid teliospores, which undergo meiosis ultimately resulting in haploid sporidia (see Refs. 1-3).Fusion of haploid cells and development of an infectious dikaryon are controlled by the a and b mating type loci. The a locus regulates cell fusion through a pheromone-based recognition system (4), and the b locus controls post-fusion steps of pathogenic development, including hyphal growth. The latter locus encodes two unrelated homeodomain proteins, bE and bW, that form heterodimers when they are derived from different alleles (5, 6). This heterodimer regulates a number of genes, among which the rep1 gene (7-10). This gene is highly expressed resulting in 2.5% of the mRNA. It encodes a preproprotein that, after processing at KEX2 recognition sites, results in 11 secreted peptides with a high sequence similarity. These peptides are localized in the cell wall of filaments, in an SDSinsoluble, but trifluoroacetic acid-extractable form (10). They are involved in formation of hydrophobic aerial hyphae (10) and in hyphal attachment to hydrophobic surfaces (11); as such they have functionally replaced hydrophobins in U. maydis (11).Hydrophobins, which are not related to the repellents, fulfill a wide spectrum of functions in fungal development (12). They do so by forming an amphipathic protein film, which consists of amyloid-like fibrils (13-15). We here show that the repellent Rep1...
The mRNAs encoding the Rev and Env proteins of simian immunodeficiency virus (SIV) are unique because upstream translation start codons are present that may modulate the expression of these viral proteins. This is true for the regular mRNAs, but we also report novel mRNA splicing variants that encode up to five upstream AUG (uAUG) codons. Their influence on Rev and Env translation was measured by mutational inactivation in reporter constructs and in the SIVmac239 strain. An intricate regulatory mechanism was disclosed that allows the virus to express a balanced amount of these two proteins. This insight also allows the design of vector constructs that efficiently express these proteins.
A novel genetic approach for the control of virus replication was used for the design of a conditionally replicating human immunodeficiency virus (HIV) variant, HIV-rtTA. HIV-rtTA gene expression and virus replication are strictly dependent on the presence of a non-toxic effector molecule, doxycycline (dox), and thus can be turned on and off at will in a graded and reversible manner. The in vivo replication capacity, pathogenicity and genetic stability of this HIV-rtTA variant were evaluated in a humanized mouse model of haematopoiesis that harbours lymphoid and myeloid components of the human immune system (HIS). Infection of dox-fed BALB Rag/γc HIS (BRG-HIS) mice with HIV-rtTA led to the establishment of a productive infection without CD4+ T-cell depletion. The virus did not show any sign of escape from dox control for up to 10 weeks after the onset of infection. No reversion towards a functional Tat–transactivating responsive (TAR) RNA element axis was observed, confirming the genetic stability of the HIV-rtTA variant in vivo. These results demonstrate the proof of concept that HIV-rtTA replicates efficiently in vivo. HIV-rtTA is a promising tool for fundamental research to study virus–host interactions in vivo in a controlled fashion.
The mRNAs encoding the Rev and Env proteins of simian immunodeficiency virus (SIV) are unique because upstream translation start codons are present that may modulate the expression of these viral proteins. We previously reported the regulatory effect of a small upstream open reading frame (ORF) on Rev and Env translation. Here we study this mechanism in further detail by modulating the strength of the translation signals upstream of the open reading frames in subgenomic reporters. Furthermore, the effects of these mutations on SIV gene expression and viral replication are analyzed. An intricate regulatory mechanism is disclosed that allows the virus to express a balanced amount of these two proteins.
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