Regulation of tomato leaf curl viral gene expression in host tissues

The regulation of expression of the two virion-sense (V1 and V2) and four complementary-sense (C1, C2, C3, and C4) open reading frames (ORFs) of Tomato leaf curl virus (TLCV) was studied in both stably and transiently transformed Nicotiana tabacum tissues with fusions with the beta-glucuronidase (GUS) reporter gene. GUS-expressing transgenic lines were obtained with each of the four complementary-sense gene-GUS fusion constructs and with truncated versions of the virion-sense gene-GUS fusion constructs (V1GUSdeltaC and V2GUSdeltaC) lacking complementary-sense sequences encoding the C1, C2, and C3 ORFs. However, little or no GUS expression was observed in kanamycin-resistant plants transformed with full-length, virion-sense gene constructs (V1GUS and V2GUS) constituting the complete viral genome. In contrast, V1GUS and V2GUS were found to direct high-level GUS expression in transient assays with tobacco protoplasts, suggesting that integration of viral constructs containing functional, complementary-sense genes may lead to repression or deletion of the introduced constructs in transgenic tissues. V2GUS expression in the transient protoplast assay was found to be severely curtailed by specific mutation of the C2 ORF, supporting a role for the C2 protein in transactivation of TLCV virion-sense gene expression. TLCV ORF-GUS constructs displayed distinctive tissue expression patterns in transgenic tobacco plants that could be divided into constitutive (C1, C4, and V2GUSdeltaC), predominantly vascular (C2, C3), or reduced expression in cells associated with the vascular bundles (V1GUSdeltaC). The significance of these results is discussed in terms of current models of gene function and regulation in geminiviruses.     

Detection of a non-structural protein of M r 11 000 encoded by the virion DNA of maize streak virus

A polypeptide of approximately 11 000 daltons (11 kDa protein) encoded by an open reading frame (10.9 ORF) from the virion sense of maize streak virus (MSV) DNA has been detected among the products of in vitro translation reactions programmed with RNA from infected maize plants and also in total protein extracts from infected leaves. The 11 kDa protein has not been detected in virions and is therefore proposed to have a nonstructural role.Viral DNA with an additional in-frame translation stop codon in the 10.9 ORF was not infectious when transmitted to maize plants via Agrobacterium tumefaciens agroinfection, suggesting that the 10.9 ORF may be essential for virus function. Computer comparison data show that equivalent ORFs in wheat dwarf virus (WDV) and digitaria streak virus (DSV) have some sequences in common with the 10.9 ORF of MSV. Further-more, the absence of similar sequences in geminiviruses which infect dicotyledonous plants suggests that the 11 kDa protein and its putative homologs in WDV and DSV have a function necessary only for those geminiviruses which infect the Gramineae.The significance of the 11 kDa protein in relation to expression of the virion sense DNA of MSV is discussed.     

Requirements for mini-exon inclusion in potato invertase mRNAs provides evidence for exon-scanning interactions in plants

Invertases are responsible for the breakdown of sucrose to fructose and glucose. In all but one plant invertase gene, the second exon is only 9 nt in length and encodes three amino acids of a five-amino-acid sequence that is highly conserved in all invertases of plant origin. Sequences responsible for normal splicing (inclusion) of exon 2 have been investigated in vivo using the potato invertase, invGF gene. The upstream intron 1 is required for inclusion whereas the downstream intron 2 is not. Mutations within intron 1 have identified two sequence elements that are needed for inclusion: a putative branchpoint sequence and an adjacent U-rich region. Both are recognized plant intron splicing signals. The branchpoint sequence lies further upstream from the 3' splice site of intron 1 than is normally seen in plant introns. All dicotyledonous plant invertase genes contain this arrangement of sequence elements: a distal branchpoint sequence and adjacent, downstream U-rich region. Intron 1 sequences upstream of the branchpoint and sequences in exons 1, 2, or 3 do not determine inclusion, suggesting that intron or exon splicing enhancer elements seen in vertebrate mini-exon systems are absent. In addition, mutation of the 3' and 5' splice sites flanking the mini-exon cause skipping of the mini-exon, suggesting that both splice sites are required. The branchpoint/U-rich sequence is able to promote splicing of mini-exons of 6, 3, and 1 nt in length and of a chicken cTNT mini-exon of 6 nt. These sequence elements therefore act as a splicing enhancer and appear to function via interactions between factors bound at the branchpoint/U-rich region and at the 5' splice site of intron 2, activating removal of this intron followed by removal of intron 1. This first example of splicing of a plant mini-exon to be analyzed demonstrates that particular arrangement of standard plant intron splicing signals can drive constitutive splicing of a mini-exon.     

Activation of a cryptic splice site in the tax gene of HTLV-I by a single nucleotide change

We identified a T-to-C mutation 2 nucleotides (nt) upstream from the AG in a GT-AG intron between exons 2 and 3 in the human T-cell leukemia virus type I (HTLV-I) tax mRNA. This mutation resulted in the preferential usage of an alternative splice site, causing a 75-nt elongation of tax mRNA and reduced production of viral antigens. When the clone containing this T-to-C mutation was reverted to the wild-type (T) DNA sequence, normal splicing of tax mRNA ensued and viral production was restored. These results suggest that the nucleotide at the position 2nt upstream from the AG in a GT-AG intron is important for the proper splicing of the HTLV-I tax gene, although it is not considered important for splicing in eukaryotes.