Ian Richard Scott

Filaggrin breakdown to water binding compounds during development of the rat stratum corneum is controlled by the water activity of the environment

Filaggrin is a specific epidermal protein which is the precursor of the free amino acids, urocanic acid and pyrrolidone carboxylic acid which are largely responsible for the ability of the stratum corneum of the skin to remain hydrated at low environmental humidity. The distribution of filaggrin shown by immunofluorescence in the stratum corneum of the rat changed dramatically during the first hours of postnatal life. During late foetal development, filaggrin accumulated through the entire thickness of the stratum corneum, indicating that there was a block on the subsequent processing of the protein which normally would convert it to free amino acids. Immediately after birth this block was lifted and normal proteolysis of the filaggrin took place in the outer part of the stratum corneum, leaving the normal adult pattern of a thin zone of cells containing filaggrin at the bottom of the stratum corneum. This activation of filaggrin proteolysis was dependent on the drop in external water activity caused by the transition from an aqueous environment in utero to a dryer environment after birth and it could be blocked by maintaining a 100% humidity atmosphere around the newborn rat after birth. In isolated stratum corneum in vitro, filaggrin proteolysis took place only between 80 and 95% relative humidity, both higher and lower relative humidity blocked the proteolysis. Application of occlusive patches to adult rats prevented the normal proteolysis of filaggrin, indicating that this mechanism controls not only the massive filaggrin proteolysis occurring after birth but also the proteolysis occurring during normal stratum corneum maturation. The stratum corneum therefore has the ability to respond to changes in external humidity by altering the level of the stratum corneum where it converts its reserves of filaggrin into water binding amino acids, such that under humid conditions water binding components will be produced in only the most superficial stratum corneum, or even not produced at all.

Histidine-rich protein of the keratohyalin granules. Source of the free amino acids, urocanic acid and pyrrolidone carboxylic acid in the stratum corneum.

The pool of free amino acids, urocanic acid and pyrrolidone carboxylic acid in mammalian stratum corneum has been shown to be derived principally or totally from the histidine-rich protein of the keratohyalin granules. The time course of appearance of free amino acids and breakdown of the histidine-rich protein are similar, as are the analyses of the free amino acids and the histidine-rich protein. Quantitative studies show that between 70 and 100% of the total stratum corneum-free amino acids are derived from the histidine-rich protein.

Histidine-rich proteins (filaggrins): Structural and functional heterogeneity during epidermal differentiation

The urea-soluble protein profiles of guinea pig, rat, mouse and human epidermis have been compared by non-equilibrium pH gradient/sodium dodecyl sulphate two-dimensional gel electrophoresis. The histidine-rich proteins (filaggrins) were identified firstly by their characteristic specificity and kinetics of labelling with [3H]histidine and [32P]phosphate, and secondly by their ability in vitro to aggregate keratin filaments specifically into bundles. In all species the phosphorylated filaggrin precursor, profilaggrin, is resolved as a single or doublet band with an apparent molecular weight greater than 300,000 and a neutral or slightly acidic iso-electric point. In striking contrast, the strongly basic filaggrins produced from similar profilaggrins form molecular weight families that are clearly species specific. In rat and man there is a single, principal molecular weight form of filaggrin (Mr 45,000 and 38,000, respectively), while mouse and guinea pig have heterogeneous families, including high molecular weight variants (Mr greater than 200,000). Even filaggrins of a particular molecular weight are not homogeneous proteins, but consist of a number of iso-electric variants, some of which are considerably less basic than the bulk of the filaggrins. Incorporation studies using [3H]arginine and [32P]phosphate indicate that the iso-electric variance is not due to residual phosphate, following profilaggrin breakdown, but rather to a conversion of basic arginine residues into neutral citrulline residues. Filaggrins of all the molecular weights from all the species studied share the ability to aggregate keratin filaments into large, insoluble macrofibrils. However, the more acidic iso-electric variants have lower affinities for keratin, particularly in man and guinea pig where the most acidic filaggrins have completely lost the ability to aggregate keratins. We discuss the possibility that a loss of keratin binding ability, resulting in a loosening of the keratin fibre/filaggrin matrix is necessary before the normal complete proteolysis of the filaggrins can occur.

Studies on the synthesis and degradation of a high molecular weight, histidine-rich phosphoprotein from mammalian epidermis.

The synthesis and subsequent fate of the histidine-rich proteins, which form a major component of keratohyalin granules in mammalian epidermis, have been studied in the guinea-pig and new-born rat. In both species the protein first synthesised is of very high molecular weight, approximately 340 000. It is short-lived and breaks down to lower molecular weight proteins 1-2 days after its synthesis. These smaller proteins differ in the two species. In the guinea-pig, the high molecular weight protein breaks down to proteins of molecular weight 250 000 and 200 000, which are themselves unstable and break down to low molecular weight species, probably amino acids. The initial breakdown of the high molecular weight protein coincides with the dispersion of the keratohyalin granules and the transition of the granular cell into the stratum corneum. This high molecular weight histidine-rich protein has been purified to homogeneity, despite its instability to several treatments during purification. The protein is highly phosphorylated, containing 6 mol% of phosphoserine, but is otherwise very basic. The possibility that dephosphorylation of the protein produces highly basic matrix proteins in the stratum corneum is discussed.

Fluorography—limitations on its use for the quantitative detection of 3H- and 14C-labeled proteins in polyacrylamide gels

The suitability of fluorography for the detection of 3H- and 14C-labeled proteins on polyacrylamide gradient gels has been investigated. It was found that the absorbance of the fluorographic film image produced by a given level of radioactivity decreased as the acrylamide concentration in the gel increased. The use of Coomassie brilliant blue protein dyes to stain the gel prior to fluorography reduced the absorbance of the fluorographic image. It is concluded that quantitative fluorography can only be applied to unstained gels of a uniform acrylamide concentration.

Does Catabolism of Stratum Corneum Proteins Yield Functionally Active Molecules

The title of this paper is a rather broad and cryptic question, so let us start by decoding and answering it. There are many stratum corneum proteins that are presumably degraded as the stratum corneum matures but one protein dominates all others on a quantitative basis. Filaggrin may comprise more than one quarter of the total protein complement of the newly formed stratum corneum cell but by the time that cell is 3-4 days old, virtually no filaggrin remains and instead the cell contains an enormously concentrated “soup” of amino acids and derivatives thereof.Ig These are the catabolised molecules-are they “functionally active?”