Flightless I is a key regulator of the fibroproliferative process in hypertrophic scarring and a target for a novel antiscarring therapy.

BACKGROUND: Hypertrophic scarring carries a large burden of disease, including disfigurement, pain and disability. There is currently no effective medical treatment to reduce or prevent hypertrophic scarring. Flightless I (Flii), a member of the gelsolin family of actin remodelling proteins, is an important negative regulator of wound repair. OBJECTIVES: The objective of this study was to investigate the role of Flii as a potential regulator of hypertrophic scarring. METHODS: Using human skin samples and an animal model of bleomycin-induced hypertrophic scarring in mice that overexpress or have reduced expression of Flii, we investigated its effect on dermal fibrosis and hypertrophic scarring. RESULTS: Flii expression was increased in human burns and hypertrophic scars. A similar increase in Flii was observed in hypertrophic scars formed in mice post-treatment with bleomycin. However, Flii-deficient (Flii(+/-) ) mice had reduced scarring in response to bleomycin evidenced by decreased dermal thickness, smaller cross-sectional scar areas, fewer myofibroblasts and a decreased collagen I/III ratio. In contrast, bleomycin-treated Flii-overexpressing mice (Flii(Tg/Tg) ) showed increased scar dermal thickness, larger cross-sectional scar areas, more myofibroblasts and an increased collagen I/III ratio. Injecting developing scars with a Flii neutralizing antibody led to a significant reduction in the size of the scars and a reduction in the collagen I/III ratio. CONCLUSIONS: This study identifies Flii as a profibrotic agent that contributes to excessive scar formation. Reducing its activity using neutralizing antibodies is a promising approach for reducing hypertrophic scarring.

Genetic, physical, and phenotypic characterization of the Del(13)Svea36H mouse.

The Del(13)Svea36H deletion was recovered from a radiation mutagenesis experiment and represents a valuable resource for investigating gene content and function at this region of mouse Chromosome (Chr) 13 and human Chr 6p21.3-23 and 6p25. In this paper we examine the physical extent of chromosome loss and construct an integrated genetic and radiation hybrid map of the deleted segment. We show that embryos which are homozygous for the deletion die at or before implantation and that heterozygotes are subviable, with a substantial proportion of carriers dying after mid-gestation but before weaning. The majority of viable carriers exhibit a variety of phenotypes including decreased size, eyes open at birth, corneal opacity, tail kinks, and craniofacial abnormalities. Both the heterozygous viability and the penetrance of the visible phenotypes vary with genetic background.

Stabilization of Xist RNA mediates initiation of X chromosome inactivation.

The onset of X inactivation is preceded by a marked increase in the level of Xist RNA. Here we demonstrate that increased stability of Xist RNA is the primary determinant of developmental up-regulation. Unstable transcript is produced by both alleles in XX ES cells and in XX embryos prior to the onset of random X inactivation. Following differentiation, transcription of unstable RNA from the active X chromosome allele continues for a period following stabilization and accumulation of transcript on the inactive X allele. We discuss the implications of these findings in terms of models for the initiation of random and imprinted X inactivation.

Reappearance of the minor alpha-sarcomeric actins in postnatal muscle.

The postnatal expression profiles of alpha-sarcomeric actin transcripts and protein are quantified in mouse striated muscles from birth to postnatal day 56 by Northern and Western blot analyses. alpha-Cardiac actin (alpha-CA) transcripts transiently increase between 12 and 21 days after birth in the quadriceps muscle, reaching approximately 90% that found in the adult mouse heart. Although alpha-CA is the alpha-sarcomeric actin isoform expressed in the immature fiber, the expression profiles of other contractile protein isoforms indicate that this postnatal period is not reflective of an immature phenotype. alpha-Skeletal actin (alpha-SA) transcripts accumulate to approximately 32% of the total alpha-sarcomeric actin transcripts in the adult heart. Our study shows that 1) there is a simultaneous reappearance of alpha-CA and alpha-SA in postnatal skeletal and heart muscles, respectively, and 2) the contractile protein gene expression profile characteristic of adult skeletal muscle is not achieved until after 42 days postnatal in the mouse. We propose there is a previously uncharacterized period of postnatal striated muscle maturation marked by the reappearance of the minor alpha-sarcomeric actins.

Isolation of novel tissue-specific genes from cDNA libraries representing the individual tissue constituents of the gastrulating mouse embryo.

A total of 5 conventional, directionally cloned plasmid cDNA libraries have been constructed from the entire embryonic region of the mid-gastrulation mouse embryo and from its four principal tissue constituents (ectoderm, mesoderm, endoderm and primitive streak). These libraries have been validated with respect to the number of independent clones, insert-size and appropriate representation of diagnostic marker genes. Subtractive hybridisation has been used to remove clones common to the Endoderm and Mesoderm cDNA libraries resulting in an Endoderm minus Mesoderm subtracted library. Probe prepared from this subtracted library has been hybridised to a grid containing approximately 18,500 Embryonic Region library clones. Three novel clones have been recovered as well as expected genes already known to be highly expressed in the primitive endoderm lineage at this stage of development. In situ hybridisation to early postimplantation embryos has revealed the expression patterns of these novel genes. One is highly expressed exclusively in visceral endoderm, one is expressed in ectodermal and endodermal tissues, and the third proves to be an early marker of prospective and differentiated surface ectoderm as well as being expressed in endoderm and its derivatives.

Multiple regions of the human cardiac actin gene are necessary for maturation-based expression in striated muscle.

In order to elucidate mechanisms involved in striated muscle contractile protein isoform expression, we have defined regulatory elements in the cardiac actin gene necessary for postnatal expression at the level of transcript accumulation in the heart and hindlimb muscles of transgenic mice. During this developmental period in the rodent, cardiac actin expression essentially remains constant in the heart, but declines significantly in skeletal muscle. We determined that a 13-kilobase human cardiac actin gene fragment contains sufficient information to direct this maturation-based developmental expression, as well as striated muscle-specific and high level expression. We localized an element responsible for maturation-based down-regulation in the 3' flank of the gene between approximately 950 and 2120 base pairs downstream of the polyadenylation site. Furthermore, we determined that -800 base pairs of 5'-flanking DNA, which contains multiple MyoD1 binding sites, as well as serum response element and AP1 binding sites, can account for striated muscle-specific expression, but not high level expression. Findings indicate that sequence(s) responsible for high level expression of the gene must be located within the body of the gene. We conclude that the human cardiac actin gene contains distinct sequences which confer developmental, tissue-specific, and high level expression.