Spam1-associated transmission ratio distortion in mice: Elucidating the mechanism

The human genome contains six hyaluronidase-like genes. Three genes (HYAL1, HYAL2 and HYAL3) are clustered on chromosome 3p21.3, and another two genes (HYAL4 and PH-20/SPAM1) and one expressed pseudogene (HYALP1) are similarly clustered on chromosome 7q31.3. The extensive homology between the different hyaluronidase genes suggests ancient gene duplication, followed by en masse block duplication, events that occurred before the emergence of modern mammals. Very recently we have found that the mouse genome also has six hyaluronidase-like genes that are also grouped into two clusters of three, in regions syntenic with the human genome. Surprisingly, the mouse ortholog of HYALP1 does not contain any mutations, and unlike its human counterpart may actually encode an active enzyme. Hyal-1 is the only hyaluronidase in mammalian plasma and urine, and is also found at high levels in major organs such as liver, kidney, spleen, and heart. A model is proposed suggesting that Hyal-2 and Hyal-1 are the major mammalian hyaluronidases in somatic tissues, and that they act in concert to degrade high molecular weight hyaluronan to the tetrasaccharide. Twenty-kDa hyaluronan fragments are generated at the cell surface in unique endocytic vesicles resulting from digestion by the glycosylphosphatidyl-inositol-anchored Hyal-2, transported intracellularly by an unknown process, and then further digested by Hyal-1. The two beta-exoglycosidases, beta-glucuronidase and beta-N-acetyl glucosaminidase, remove sugars from reducing termini of hyaluronan oligomers, and supplement the hyaluronidases in the catabolism of hyaluronan.

We have analyzed intracellular distributions of mRNAs for the cytoskeletal proteins actin, vimentin, and tubulin by in situ hybridization. Although polyadenylated RNA was homogeneously distributed throughout the cell, actin mRNA demonstrated a nonhomogeneous distribution in 95% of randomly selected chicken embryonic myoblasts and fibroblasts, as detected by isotopic and nonisotopic techniques. Actin mRNA concentrations were highest at cell extremities, generally in lamellipodia, where grain densities were up to 16-fold higher than in areas near the nucleus. Vimentin mRNA, unlike actin mRNA, was distributed near the nucleus. Tubulin mRNA appeared most concentrated in the peripheral cytoplasm. These results demonstrate that cytoplasmic mRNAs are localized in specific, nonrandom cellular patterns and that localized concentrations of specific proteins may result from corresponding localization of their respective mRNAs. Hence, actin mRNA distribution may result in increased concentration of actin filaments in lamellipodia of motile cells.

Recent evidence suggests that gene expression may be regulated, at least in part, at post-transcriptional level by factors inducing the extremely rapid degradation of messenger RNAs. These factors include reactions between adenyl-uridyl-rich elements (AREs) of the relevant mRNA and either specific proteins that bind to these elements or exosomes. This review deals with examples of the proteins (AU-rich binding proteins, AUBPs) and exosomes, which have been shown to form complexes with AREs and bring about rapid degradation of the relevant mRNA, and with certain other factors, which protect the RNA from such degradation. The biochemical and physiological factors underlying the stability of messenger RNAs carrying the ARE motifs will be reviewed in the light of their emerging significance for cell physiology, human pathology, and molecular medicine. We also consider the possible application of the results of recent insights into the mechanisms to pharmacological interventions to prevent or cure disorders, especially developmental disorders, which the suppression of gene expression may bring about. Molecular targeting of specific steps in protein degradation by synthetic compounds has already been utilized for the development of pharmacological therapies. Copyright 2003 Wiley-Liss, Inc.