The human hyaluronan synthase genes: genomic structures, proximal promoters and polymorphic microsatellite markers.

The glycosaminoglycan (GAG) hyaluronan (HA) is a key component of the vertebrate extracellular matrix (ECM) and is synthesised by the HA synthase (HAS) enzymes HAS1, HAS2 and HAS3 at the plasma membrane. Accumulating evidence emphasises the relevance of HA metabolism in an increasing number of processes of clinical interest including renal fibrosis and peritoneal mesothelial wound healing. In the present study, the genomic sequences and organisation of the genes encoding the human HAS isoforms were deduced, in silico, from reference cDNA and genomic sequence data. These data were confirmed in vitro by sequencing of PCR-amplified HAS exons and flanking genomic sequences, comparison with sequence data for the corresponding murine Has orthologues, rapid amplification of 5' cDNA ends analysis and luciferase reporter assays on putative proximal promoter sequences. The HAS1 gene comprised five exons, with the translation start site situated 9bp from the 3' end of exon 1. In contrast, the genomic structures for HAS2 and both HAS3 variants spanned four exons, exon 1 forming a discrete 5'-untranslated region (5'-UTR) and the translation start site lying at nucleotide 1 of exon 2. Dinucleotide microsatellite loci were identified in intron 1 of HAS1 and HAS2, and immediately upstream of the HAS3 gene and their utility as linkage markers demonstrated in genomic DNA (gDNA) studies. We thus present a comprehensive resource for mutation detection screening of all HAS exons and/or linkage analysis of each HAS gene in a variety of disorders for which they are attractive candidates.

Induction of hyaluronan synthase 2 by human chorionic gonadotropin in mural granulosa cells of equine preovulatory follicles.

In contrast to other species, the preovulatory rise in gonadotropins in mares causes a remarkable expansion of the entire granulosa cell layer in vivo, suggesting that hyaluronan (HA) synthesis may be regulated in mural granulosa cells in this species. The objectives of this study were to clone and characterize equine hyaluronan synthase 2 (HAS2) and investigate the regulation of its transcript and of HA synthesis in equine follicles during human chorionic gonadotropin (hCG)- induced ovulation. Results showed that the equine HAS2 cDNA contains a 5'-untranslated region of 436 bp, an open reading frame of 1659 bp, and a 3'-untranslated region of 707 bp. The open reading frame encodes a 552-amino acid protein that is highly conserved (98-99% identity), compared with other known mammalian homologs. The regulation of HAS2 mRNA was studied in equine follicles isolated during estrus between 0 and 39 h after an ovulatory dose of hCG and in corpora lutea obtained on d 8 of the estrous cycle. Results from semiquantitative RT-PCR/Southern blotting analyses revealed a transient induction of HAS2 during the ovulatory process. Levels of HAS2 transcripts were undetectable in follicles before hCG treatment (0 h), increased markedly after gonadotropin treatment (P < 0.05), but returned to undetectable levels in corpora lutea. Analyses performed on isolated preparations of theca interna and granulosa cells showed that the granulosa cell layer was the predominant site of HAS2 expression. An immunohistochemical approach showed that this induction of HAS2 transcript was accompanied by a dramatic increase in HA production after hCG treatment. The isolation and characterization of a 1.8-kb fragment of genomic sequence located immediately upstream of equine HAS2, and comparison with corresponding human and mouse genomic regions identified several conserved putative cis-acting elements. Thus, this study describes the primary structure of equine HAS2, demonstrates for the first time the regulation of HAS2 in mural granulosa cells during the ovulatory process in vivo and identifies a valuable model in which to study the molecular control of HAS2 gene expression.

Hyaluronan synthesis induces microvillus-like cell surface protrusions.

Hyaluronan synthases (HASs) are plasma membrane enzymes that simultaneously elongate, bind, and extrude the growing hyaluronan chain directly into extracellular space. In cells transfected with green fluorescent protein (GFP)-tagged Has3, the dorsal surface was decorated by up to 150 slender, 3-20-microm-long microvillus-type plasma membrane protrusions, which also contained filamentous actin, the hyaluronan receptor CD44, and lipid raft microdomains. Enzymatic activity of HAS was required for the growth of the microvilli, which were not present in cells transfected with other GFP proteins or inactive GFP-Has3 mutants or in cells incubated with exogenous soluble hyaluronan. The microvilli induced by HAS3 were gradually withered by introduction of an inhibitor of hyaluronan synthesis and rapidly retracted by hyaluronidase digestion, whereas they were not affected by competition with hyaluronan oligosaccharides and disruption of the CD44 gene, suggesting independence of hyaluronan receptors. The data bring out the novel concept that the glycocalyx created by dense arrays of hyaluronan chains, tethered to HAS during biosynthesis, can induce and maintain prominent microvilli.

Natural antisense mRNAs to hyaluronan synthase 2 inhibit hyaluronan biosynthesis and cell proliferation.

We report the identification of a natural antisense mRNA of hyaluronan synthase 2 that we have chosen to designate as HASNT (for HA synthase 2 antisense) in human and mouse. HASNT is transcribed from the opposite strand of the HAS2 gene locus and is represented by several independent expressed sequence tags in human. Portions of the mouse Hasnt gene were identified through an exon-trapping approach. Sequence conservation is extremely low between human and mouse HASNT, and it is not clear whether these mRNAs contain functional open reading frames. HASNT has an alternate splice site in both human and mouse. This splice site is located at an identical position within the gene in both species and results in mRNAs of two different lengths. In each species, the antisense portion of the HASNT gene is complementary to the first exon of HAS2, which represents the 5'-untranslated region. To study the biological activity of HASNT, two human expressed sequence tag clones, representing long and short HASNT splice variants, were cloned into a tetracycline-inducible vector and were stably transfected into human osteosarcoma U2-OS Tet-on cells. The long and short HASNT-expressing cells had a reduction in HAS2 mRNA levels up to 94 and 86%, respectively, whereas hyaluronan biosynthesis was inhibited by 40 and 37%, respectively. Cell proliferation was reduced throughout the time frame of the experiment. Exogenous high molecular mass hyaluronan failed to rescue the suppressed cell proliferation, whereas adenoviral-mediated overexpression of hyaluronan synthase 3, which stimulated endogenous hyaluronan biosynthesis, was able to rescue. Collectively, our data suggest that natural antisense mRNAs of HAS2 are able to regulate HAS2 mRNA levels and hyaluronan biosynthesis in a cell culture model system and may have an important and novel regulatory role in the control of HAS2, HA biosynthesis, and HA-dependent cell functions in vivo.

Three vertebrate hyaluronan synthases are expressed during mouse development in distinct spatial and temporal patterns.

We have used in situ hybridization to study the expression of the vertebrate hyaluronan synthase (Has) gene family members, designated Has1, Has2, and Has3, during mouse development. At embryonic day (E) 7.5, Has1 and Has2 are expressed throughout the gastrulating embryo. After E8.5, Has1 expression disappears, but Has2 continues to be strongly, albeit transiently, expressed in numerous tissues, including the branchial arches and craniofacial structures such as the palatal shelves and lens pit. Has2 is also expressed during cardiac, skeletal, and tail development. Has3 transcripts are first detected at E10.5 in the maxillary and mandibular components of the first branchial arch. Notably, Has3 expression in the developing teeth, vibrissae hair follicles, nasal cavity, and inner ear complements the expression pattern of Has2. Our results indicate that, whereas Has2 is exclusively expressed in some tissues, its expression pattern overlaps and/or complements that of Has1 and Has3 in others.

Plasma membrane residence of hyaluronan synthase is coupled to its enzymatic activity.

Hyaluronan is a multifunctional glycosaminoglycan up to 10(7) Da molecular mass produced by the integral membrane glycosyltransferase, hyaluronan synthase (HAS). When expressed in keratinocytes, N-terminally tagged green fluorescent protein-HAS2 and -HAS3 isoenzymes were found to travel through endoplasmic reticulum (ER), Golgi, plasma membrane, and endocytic vesicles. A distinct enrichment of plasma membrane HAS was found in cell protrusions. The total turnover time of HAS3 was 4-5 h as judged by the green fluorescent protein signal decay and hyaluronan synthesis inhibition in cycloheximide-treated cells. The transfer from ER to Golgi took about 1 h, and the dwell time on the plasma membrane was less than 2 h in experiments with a relief and introduction, respectively, of brefeldin A. Constructs of HAS3 with 16- and 45-amino-acid C-terminal deletions mostly stayed within the ER, whereas a D216A missense mutant was localized within the Golgi complex but not the plasma membrane. Both types of mutations were almost or completely inactive, similar to the wild type enzyme that had its entry to the plasma membrane experimentally blocked by brefeldin A. Inhibition of hyaluronan synthesis by UDP-glucuronic acid starvation using 4-methyl-umbelliferone also prevented HAS access to the plasma membrane. The results demonstrate that 1) a latent pool of HAS exists within the ER-Golgi pathway; 2) this pool can be rapidly mobilized and activated by insertion into the plasma membrane; and 3) inhibition of HAS activity through mutation or substrate starvation results in exclusion of HAS from the plasma membrane.

The role of hyaluronan synthase 3 in ventilator-induced lung injury.

We recently found that low-molecular-weight hyaluronan was induced by cyclic stretch in lung fibroblasts and accumulated in lungs from animals with ventilator-induced lung injury. The low-molecular-weight hyaluronan produced by stretch increased interleukin-8 production in epithelial cells, and was accompanied by an upregulation of hyaluronan synthase-3 mRNA. We hypothesized that low-molecular-weight hyaluronan induced by high VT was dependent on hyaluronan synthase 3, and was associated with ventilator-induced lung injury. Effects of high VT ventilation in C57BL/6 wild-type and hyaluronan synthase-3 knockout mice were compared. Significantly increased neutrophil infiltration, macrophage inflammatory protein-2 production, and lung microvascular leak were found in wild-type animals ventilated with high VT. These reactions were significantly reduced in hyaluronan synthase-3 knockout mice, except the capillary leak. Wild-type mice ventilated with high VT were found to have increased low-molecular-weight hyaluronan in lung tissues and concomitant increased expression of hyaluronan synthase-3 mRNA, neither of which was found in hyaluronan synthase-3 knockout mice. We conclude that high VT induced low-molecular-weight hyaluronan production is dependent on de novo synthesis through hyaluronan synthase 3, and plays a role in the inflammatory response of ventilator-induced lung injury.

A hyaluronan binding link protein gene family whose members are physically linked adjacent to chondroitin sulfate proteoglycan core protein genes: the missing links.

We describe a vertebrate hyaluronan and proteoglycan binding link protein gene family (HAPLN), consisting of four members including cartilage link protein. The encoded proteins share 45-52% overall amino acid identity. In contrast to the average sequence identity between family members, the sequence conservation between vertebrate species was very high. Human and mouse link proteins share 81-96% amino acid sequence identity. Two of the four link protein genes (HAPLN2 and HAPLN4) were restricted in expression to the brain/central nervous system, while one of the four genes (HAPLN3) was widely expressed. Genomic structures revealed that all four HAPLN genes were similar in exon-intron organization and were also similar in genomic organization to the 5' exons for the CSPG core protein genes. Strikingly, all four HAPLN genes were located immediately adjacent to the four CSPG core protein genes creating four pairs of CSPG-HAPLN genes within the mammalian genome. Furthermore, the two brain-specific HAPLN genes (HAPLN2 and HAPLN4) were physically linked to the brain-specific CSPG genes encoding brevican and neurocan, respectively. The tight physical association of the HAPLN and CSPG genes supports a hypothesis that the first HAPLN gene arose as a partial gene duplication event from an ancestral CSPG gene. There is some degree of coordinated expression of each gene pair. Collectively, the four HAPLN genes are expressed by most tissue types, reflecting the fundamental importance of the hyaluronan-dependent extracellular matrix to tissue architecture and function in vertebrate species. Comparison of the genomic structures for the HAPLN, CSPG genes and other members of the link module superfamily provide strong support for a common evolutionary origin from an ancestral gene containing one link module encoding exon.

Hyaluronan and morphogenesis.

In the past decade, there has been an explosion of interest in hyaluronan, an often misunderstood, biochemically simple, yet functionally complex carbohydrate polymer that is a resident of many extracellular matrices. Previously thought of as a passive, space-filling component of the extracellular matrix, the so-called "goo" concept, hyaluronan has risen to a much higher regard in recent years, even being called "magic glue" in a recent perspective. Hyaluronan is likely to be the common thread in many morphogenetic processes, including condensation events and epithelial-to-mesenchymal transformation. Hyaluronan is comparatively unique as a component of the extracellular matrix as it is solely composed of carbohydrate. In order to truly understand this biopolymer, one must first understand its biosynthesis, then understand its uptake and turnover, then identify its binding proteins and receptors. Major advances have been made in all of these arenas within the past decade. Hyaluronan synthases, hyaluronidases, and the hyaladherins have been molecularly identified and cloned. Furthermore, many have now been inactivated, employing gene targeting strategies, to create mice deficient in the respective gene product function. Collectively, huge strides have been made in our understanding of the diverse biological functions for this fascinating molecule. Hyaluronan appeared in metazoans immediately prior to the arrival of the vertebrates, and may be required for the differentiation, development, and/or function of most cell lineages, structures, and tissues that we associate with vertebrates, such as the neural crest, the skeleton, including the teeth, skin, and hair, and the chambered heart. In this review, we will update the reader on the advances of the past decade and provide insight into those morphogenetic processes through which hyaluronan regulates vertebrate development.

Investigation of hyaluronan function in the mouse through targeted mutagenesis.

It has become increasingly apparent that the high molecular mass glycosaminoglycan, hyaluronan (HA), is required for many morphogenetic processes during vertebrate development. This renewed understanding of the various developmental roles for HA, has come about largely through the advent of gene targeting approaches in the mouse. To date, mutations have been engineered in the enzymes responsible for biosynthesis and degradation and for those proteins that bind to HA within the extracellular matrix and at the cell surface. Collectively, the phenotypes resulting from these mutations demonstrate that HA is critical for normal mammalian embryogenesis and for various processes in postnatal and adult life (Table 1). In this article we will review our progress in understanding the biological functions for HA through targeted mutagenesis of the HA synthase 2 (Has2) and 3 (Has3) genes. Data that has been obtained from a conventional targeted disruption of the Has2 gene, is presented in an accompanying review by Camenisch and McDonald. More specifically, in this review we will provide an overview of the conditional gene targeting strategy being used to create tissue-specific deficiencies in Has2 function, along with our progress in understanding the role for Has3-dependent HA biosynthesis.

Manipulation of hyaluronan synthase expression in prostate adenocarcinoma cells alters pericellular matrix retention and adhesion to bone marrow endothelial cells.

Prostate cancer metastasis to bone marrow involves initial adhesion of tumor cells to the bone marrow endothelium, followed by transmigration and proliferation within the marrow. Rapid, specific adhesion of highly metastatic prostate adenocarcinoma cells (PC3M-LN4) to bone marrow endothelial cell (BMEC) lines requires a pericellular hyaluronan (HA) matrix and correlates with dramatically up-regulated HA synthase (HAS) expression. Non-metastatic prostate tumor cells (LNCaP) do not assemble a HA matrix, adhere poorly to BMECs, and express normal levels of HAS. Preferential bone metastasis of prostate carcinoma cells may therefore be facilitated by tumor cell HA biosynthesis. In this report, HAS gene expression was manipulated to investigate the direct impact of prostate tumor cell HA production on adhesion to BMECs. PC3M-LN4 cells stably transfected with antisense HAS2 and HAS3 failed to form pericellular matrices. Adhesion of these transfectants to BMECs was significantly diminished, comparable to the low level exhibited by LNCaP cells. Upon transfection with full-length HAS2 or HAS3, the non-adherent LNCaP cells retained pericellular HA and adhered to BMECs. The results of this study are consistent with a model in which HA matrix formation, BMEC adhesion, and metastatic potential are mediated by HAS expression.

Identification and analysis of the promoter region of the human hyaluronan synthase 2 gene.

Hyaluronan (HA) is a linear glycosaminoglycan of the vertebrate extracellular matrix that is synthesized at the plasma membrane by the HA synthase (HAS) enzymes HAS1, -2 and -3. The regulation of HA synthesis has been implicated in a variety of extracellular matrix-mediated and pathological processes, including renal fibrosis. We have recently described the genomic structures of each of the human HAS genes. In the present study, we analyzed the HAS2 promoter region. In 5'-rapid amplification of cDNA ends analysis of purified mRNA from human renal epithelial proximal tubular cells, we detected an extended sequence for HAS2 exon 1, relocating the transcription initiation site 130 nucleotides upstream of the reference HAS2 mRNA sequence, GenBank accession number NM_005328. A luciferase reporter gene assay of nested fragments spanning the 5' terminus of NM_005328 demonstrated the constitutive promoter activity of sequences directly upstream of the repositioned transcription initiation site but not of the newly designated exonic nucleotides. Using reverse transcription-PCR, expression of this extended HAS2 mRNA was demonstrated in a variety of human cell types, and orthologous sequences were detected in mouse and rat kidney. Alignment of human, murine, and equine genomic DNA sequences upstream of the repositioned HAS2 exon 1 provided evidence for the evolutionary conservation of specific transcription factor binding sites. The location of the HAS2 promoter will facilitate analysis of the transcriptional regulation of this gene in a variety of pathological contexts as well as in developmental models in which HAS2 null animals have an embryonic lethal phenotype.