Intracranial volume (ICV) in isolated sagittal craniosynostosis measured by 3D photocephalometry: A new perspective on a controversial issue.

BACKGROUND: There are still controversies regarding the intracranial volumes in patients with isolated sagittal craniosynostosis compared to a healthy population. This study aimed to compare the intracranial volume of children with sagittal synostosis and scaphocephaly to an age- and gender-matched control cohort using three-dimensional (3D) photogrammetry. METHODS: 62 boys and nine girls with sagittal craniosynostosis were included in this study. The intracranial volume was measured at the first clinical presentation. However, 3D photogrammetry was performed at children not younger than 3 months. The 3D photogrammetric data of 547 healthy boys and 287 healthy girls between the ages of 3-10 month was analyzed to establish an age- and gender-matched control group. RESULTS: Male patients with sagittal synostosis showed a significantly reduced intracranial volume compared to the reference group. For female patients, the intracranial volume was slightly lower compared to the norm group, but not significantly. CONCLUSIONS: Male children with sagittal synostosis showed significantly decreased intracranial volume between the age of 3 and 10 months compared to an age- and gender-matched control group. Female patients in the same age group presented a lower intracranial volume compared to the norm group. Measuring intracranial volume using 3D photogrammetry is a comparable and valuable alternative to CT scans that leads to a significant reduction of radiation exposure to the growing brain.

TIF-IA, the factor mediating growth-dependent control of ribosomal RNA synthesis, is the mammalian homolog of yeast Rrn3p.

Cells carefully modulate the rate of rRNA transcription in order to prevent an overinvestment in ribosome synthesis under less favorable nutritional conditions. In mammals, growth-dependent regulation of RNA polymerase I (Pol I) transcription is mediated by TIF-IA, an essential initiation factor that is active in extracts from growing but not starved or cycloheximide-treated mammalian cells. Here we report the molecular cloning and functional characterization of recombinant TIF-IA, which turns out to be the mammalian homolog of the yeast factor Rrn3p. We demonstrate that TIF-IA interacts with Pol I in the absence of template DNA, augments Pol I transcription in vivo and rescues transcription in extracts from growth-arrested cells in vitro.

Construction of infectious feline foamy virus genomes: cat antisera do not cross-neutralize feline foamy virus chimera with serotype-specific Env sequences.

Full-length genomes of the feline foamy virus (FFV or FeFV) isolate FUV were constructed. DNA clone pFeFV-7 stably directed the expression of infectious FFV progeny virus indistinguishable from wild-type, uncloned FFV isolate FUV. The env and bel 1 genes of pFeFV-7 were substituted for by corresponding sequences of the FFV serotype 951 since previous studies implicated a defined part of FFV Env protein as responsible for serotype-specific differences in serum neutralization (I. G. Winkler, R. M. Flügel, M. Löchelt, and R. L. P. Flower, 1998. Virology 247: 144-151). Recombinant virus derived from chimeric plasmid pFeFV-7/951 containing the hybrid env gene and the parental clone pFeFV-7 were used for neutralization studies. By means of a rapid titration assay for FFV infectivity, we show that progeny virus derived from plasmid pFeFV-7 was neutralized by FUV- but not by 951-specific antisera, whereas pFeFV-7/951-derived chimeric virus was neutralized by 951-specific antisera only. Both recombinant proviruses will be useful for repeated delivery of foreign genes for therapeutic gene applications into cats.

Genomic structure, alternative transcripts and chromosome location of the human LIM domain binding protein 1 gene LDB1.

By protein interaction screening using a radioactive LMO2 protein probe we have isolated a LIM domain binding protein. The gene shows high homology to independently isolated genes from mouse, Xenopus and Drosophila called Ldb1/Nli/Clim-2, Xldb1 and Chip, respectively. The human and mouse genes differ by only two amino acids, suggesting that the gene that we have isolated is the human homologue. Here we describe the genomic organization, alternative transcript forms and the chromosome mapping of the human gene LDB1 (alias NLI). The gene is spread over at least 12 kb and has 11 exons. Preceding the described ATG initiation site in the mouse a highly conserved region between mouse, chicken and human was detected with a second possible in frame initiation site coding for further 36 amino acids. An alternative splice site adding six nucleotides corresponding to the addition of two amino acids at the end of exon 10 was found. The gene was mapped to chromosome 10q24-->q25 by in situ hybridization, a region frequently deleted in many types of cancer. Fine mapping with a radiation hybrid panel localized the gene in the interval between the markers D10S603 and D10S540.

Nuclear localization of the functional Bel 1 transactivator but not of the gag proteins of the feline foamy virus.

Interactions between host cells and foamy or spumaretroviruses are different from those of other known retroviruses. Previous work has suggested that the Gag and high-affinity DNA-binding Bel 1 transactivator of human foamy virus are localized in the nuclei of infected cells. Using two independent detection methods, we show here that the functionally active Bel 1 transactivator protein of feline foamy virus is of nuclear localization. In contrast to that reported for the human foamy virus Gag protein, the cat foamy virus Gag proteins exclusively localized in the cytoplasm close to perinuclear regions.

Detection of subgenomic cDNAs and mapping of feline foamy virus mRNAs reveals complex patterns of transcription.

Feline foamy virus (FeFV) belongs to the group of spumaretroviruses that contain in addition to gag, pol, and env accessory genes collectively called bel genes. Primate FVs have been shown to utilize internal promoters in addition to the 5' LTR promoters. In contrast to other known retroviruses, the FV pol genes are expressed via spliced transcripts. Northern blot analysis and reverse transcription-coupled polymerase chain reactions (RT-PCR) were used to amplify, clone, and characterize cDNAs generated from subgenomic viral transcripts. Sequencing of the splice site junctions of the different FeFV mRNAs showed that singly and multiply spliced subgenomic transcripts were expressed in virus-infected cells. The relative amount of the spliced pol-specific transcripts was quantitated and FeFV pol mRNA found to be expressed at about one-half of that of the genomic mRNA. The major FeFV internal start site of transcription was identified at RNA position 7925. Comparison of the FeFV transcriptional patterns to those of the human foamy virus revealed that the FeFV bel 1 mRNA was expressed exclusively from the internal promoter in contrast to primate foamy viruses that use both the LTR and the internal promoter for Bel 1 expression. Unexpectedly, an env-bel 2 mRNA was identified in FeFV-infected cells. In addition, cDNAs from FeFV-infected cells were directly amplified by PCR without RT reactions and found to correspond to genomic and to a subset of different subgenomic FeFV mRNAs.

Characterization of the genome of feline foamy virus and its proteins shows distinct features different from those of primate spumaviruses.

The genome of the feline foamy virus (FeFV) isolate FUV was characterized by molecular cloning and nucleotide sequence analysis of subgenomic proviral DNA. The overall genetic organization of FeFV and protein sequence comparisons of different FeFV genes with their counterparts from other known foamy viruses confirm that FeFV is a complex foamy virus. However, significant differences exist when FeFV is compared with primate foamy viruses. The FeFV Gag protein is smaller than that of the primate spumaviruses, mainly due to additional MA/CA sequences characteristic of the primate viruses only. Gag protein sequence motifs of the NC domain of primate foamy viruses assumed to be involved in genome encapsidation are not conserved in FeFV. FeFV Gag and Pol proteins were detected with monospecific antisera directed against Gag and Pol domains of the human foamy virus and with antisera from naturally infected cats. Proteolytic processing of the FeFV Gag precursor was incomplete, whereas more efficient proteolytic cleavage of the pre125Pro-Pol protein was observed. The active center of the FeFV protease contains a Gln that replaces an invariant Gly residue at this position in other retroviral proteases. Functional studies on FeFV gene expression directed by the promoter of the long terminal repeat showed that FeFV gene expression was strongly activated by the Bell/Tas transactivator protein. The FeFV Bell/Tas transactivator is about one-third smaller than its counterpart of primate spumaviruses. This difference is also reflected by a limited sequence similarity and only a moderate conservation of structural motifs of the different foamy virus transactivators analyzed.

A rapid streptavidin-capture ELISA specific for the detection of antibodies to feline foamy virus.

We report a simple procedure for the rapid development of an ELISA with the potential for wide application to any defined protein antigen. The procedure involves the expression of protein encoded by a PCR product, using a commercially available T-vector that adds a biotin tag, and a single step purification by affinity for streptavidin for direct use in ELISA. In our experiments, a recombinant protein from the nucleocapsid domain of the feline foamy virus gag gene was expressed as a fusion protein with a biotin tag and then applied directly to streptavidin-coated ELISA wells. An extract from a clone with the insert in antisense orientation was used as a control. Non-specific reactions with antigen extracts from both sense and antisense clones were observed in 6 of the 376 (1.6%) sera tested. Antibody to feline foamy virus, which forms a stable persistent infection in cats, was detected in 107 of 201 (53%) Australian cats, but none of 175 sera from veterinarians. There was a 100% correlation between FeFV antibody detected by ELISA, immunoblot, serum neutralisation and virus isolation, confirming that this test is sensitive and specific.

Regulation of gene expression by human foamy virus and potentials of foamy viral vectors.

The hallmarks of the spumaretrovirus or human foamy virus (HFV) are summarized and discussed with special focus on the potentials to use HFV as a new retroviral vector system. The special features of HFV are the expression of pol by splicing and start of translation at a defined initiation codon. The first Met of Pol is conserved in the six known foamy virus genomic sequences. Another remarkable characteristic of HFV is the presence of a Gly-Arg-rich sequence instead of the Cys-Cys motif of the classical retroviral nuclecapsid proteins. The preferential budding of HFV into cytoplasmic vesicles and the potential to exploit it in the application of corresponding vector systems is discussed. In addition, recent reports of transducing marker genes into susceptible cells will be reviewed.

Characterization of the spliced pol transcript of feline foamy virus: the splice acceptor site of the pol transcript is located in gag of foamy viruses.

Foamy viruses, or spumaviruses, are distinct members of the Retroviridae. Here we have characterized the long terminal repeat of the feline, or cat, foamy virus by determining the locations of the transcriptional start site and the poly(A) addition site. The splice donor and splice acceptor sites of the subgenomic mRNA responsible for Pro-Pol protein expression were identified by nucleotide sequencing of the corresponding cDNAs. The leader exon of the feline foamy virus is 57 nucleotides long. The splice acceptor of the subgenomic pol mRNA was found to be located in gag. The location of the splice acceptor of the human foamy virus pol mRNA was confirmed to map in gag. The pol splice acceptor site in gag of the cat foamy virus is located further downstream than that of human foamy virus.

A single ancestral gene of the human LIM domain oncogene family LMO in Drosophila: characterization of the Drosophila Dlmo gene.

Members of the human TTG/RBTN family, now renamed 'LMO' for LIM-only proteins, encode proteins with two tandem copies of a LIM motif. There are three members of this family, two have been isolated at the sites of chromosomal translocations in T-cell leukaemia. The function of the LIM motifs is at present unknown. We found that the LMO-2 gene is highly conserved between mammals, Drosophila and yeast. As a first step to obtain a model system for studying the function of the LIM motifs we have isolated the Drosophila homologue Dlmo. In contrast to mammals Drosophila appears to have only one lmo gene. A 2087 bp cDNA clone was isolated from a larval cDNA library, encoding a protein of 266 amino acids. A second transcript with an alternative 5' end was identified in RNA from embryos. The Drosophila lmo protein consists of two tandem copies of the conserved LIM domain characteristic of the human LMO family and an extended amino and carboxy terminus, which is not present in the human proteins. The amino acid sequence similarity with human LMO-1 and LMO-2 in LIM 1 is 79% and 69% and in LIM-2 90% and 60%, respectively. In addition a short stretch of 25 nucleotides with a homology of 83% between LMO-2 and Dlmo is found in the 3' UTR. Dlmo, like LMO-1, has an intron after the second LIM encoding region, which is not present in LMO-2. It is expressed maternally and at a high level in early embryogenesis as well as in adults. Interestingly we observed that the Dlmo protein is immunologically related to LMO-2 and can be detected by immunohistochemistry in early cellular blastoderm embryos. The gene was localised to a genetically well characterized region (17C on the X chromosome) opening the way for identification of mutations.