Faculty Bibliography

Microfibrils having a diameter of 10-12 nm, found either in association with elastin or independently, are an important component of the extracellular matrix of many tissues, but characterization of these microfibrils is incomplete. To further our understanding of the gene structure of proteins composing the microfibrils and to identify their chromosomal location, we have cloned and characterized another microfibril protein, designated microfibril-associated protein-3 (MFAP3). The human gene encoding MFAP3 has a very simple structure, containing only two translated exons encoding a protein of 362 amino acids. Monospecific antibodies prepared against the recombinantly expressed protein reacted with the microfibrils found in ocular zonules. MFAP3 does not appear to share homology with any other known protein. The gene was found to be located on chromosome 5q32-q33.2, near the locus 5q21-q31 reported for the fibrillin gene, FBN2, which has been linked to congenital contractural arachnodactyly. MFAP3 is a candidate gene for heritable diseases affecting microfibrils

The isolation and characterization of cDNAs encompassing the full length of chicken, cow, rat and human elastin mRNA have led to the elucidation of the primary structure of the respective tropoelastins. Large segments of the sequence are conserved but there are also considerable variations which range in extent from relatively small alterations, such as conservative amino acid substitutions, to variation in the length of hydrophobic segments and largescale deletions and insertions. In general, smaller differences are found among mammalian tropoelastins and greater ones between chicken and mammalian tropoelastins. Although only a single elastin gene is found per haploid genome, the primary transcript is subject to considerable alternative splicing, resulting in multiple tropoelastin isoforms. Functionally distinct hydrophobic and cross-link domains of the protein are encoded in separate exons which alternate in the gene. The introns of the human gene are rich in Alu repetitive sequences, which may be the site of recombinational events, and there are also several dinucleotide repeats, which may exhibit polymorphism and, therefore, be effective genetic markers. The 5' flanking region is G+C rich and contains potential binding sites for numerous modulating factors, but no TATA box or functional CAAT box. The basic promoter is contained within a 136 bp segment and transcription is initiated at multiple sites. These findings suggest that the regulation of elastin gene expression is complex and takes place at several levels

Microfibril-associated glycoprotein (MAGP) is an integral component of microfibrillar structures that play a critical role in the organization of elastic fibers in the extracellular matrix. To study possible molecular interactions between MAGP and other elastic fiber components, we have generated native MAGP using a baculovirus expression system and tested its ability to associate with tropoelastin and fibrillin. MAGP produced by SF9 cells underwent processing similar to the mammalian protein, including correct cleavage of the signal peptide and sulfation of tyrosine residues. When tested in solid-phase binding assays, native MAGP specifically bound to tropoelastin but not fibrillin-1. Binding to tropoelastin was divalent cation-independent and was completely blocked by reduction and alkylation of either protein. Antibody inhibition studies indicated that the carboxyl terminus of tropoelastin mediated its interaction with MAGP. In addition to binding to elastin, MAGP was also a substrate for transglutaminase, which might explain its propensity to form high molecular weight aggregates that cannot be dissociated with reduction or denaturation. Together, the results of this study provide new insights into the functional relationship between microfibrillar proteins and have important implications for understanding elastic fiber assembly

5-Chloro[1,4-13C]levulinic acid ([1,4-13C]CLA) is an active site-directed inactivator of porphobilinogen synthase (PBGS). PBGS asymmetrically condenses two molecules of 5-aminolevulinic acid (ALA) which are called A-side ALA and P-side ALA in reference to their fates as the acetyl and propionyl halves of the product. [1,4-13C]CLA modifies bovine PBGS at the A-side ALA binding site. The C4 chemical shift indicates an intact keto moiety; the C1 chemical shift indicates a deprotonated carboxyl group. In contrast, [1,4-13C]CLA modification of Escherichia coli PBGS is heterogeneous and occurs preferentially at the P-side ALA binding site. The C1 chemical shifts indicate substantially deprotonated carboxylic acid groups. For one of four observed forms of [1,4-13C]CLA-modified E. coli PBGS, an analog of the P-site Schiff base is found. Bovine and E. coli PBGS contain two different zincs, ZnA and ZnB. Past results placed ZnA near A-side ALA. [1,4-13C]CLA modifies E. coli PBGS at Cys119 or Cys129, which is part of a four-cysteine cluster implicated in binding ZnB. This result places ZnB near P-side ALA. E. coli PBGS binds a third type of divalent metal, MgC or MnC, which is found to have no significant effect on the 13C NMR spectrum of the [1,4-13C]CLA-modified protein

Microfibrils with a diameter of 10-12 nm, found either in association with elastin or independently, are an important component of the extracellular matrix of many tissues. To extend our understanding of the proteins composing these microfibrils, the cDNA and gene encoding the human associated microfibril protein (MFAP1) have been cloned and characterized. The coding portion is contained in 9 exons, and the sequence is very homologous to the previously described chick cDNA, but does not appear to share homology or domain motifs with any other known protein. Interestingly, the gene has been localized to chromosome 15q15-q21 by somatic hybrid cell and chromosome in situ analyses. This is the same chromosomal region to which the fibrillin gene, FBN1, known to be defective in the Marfan syndrome, has been mapped. MFAP1 is a candidate gene for heritable diseases affecting microfibrils

The M and N human blood group antigens are complex glycopeptide determinants at the amino terminus of the red blood cell membrane glycoprotein, glycophorin A. The heavy and light chain variable region cDNA sequences were determined for seven murine monoclonal antibodies recognizing glycophorin A. Three of the antibodies were anti-M and four were anti-N. Each of the anti-M antibodies was composed of VH and VL regions derived from distinct germline gene families (VH1 (J558), VH4 (X24), VH5 (7183), VK5, VK8, and VK19). In contrast, all four anti-N heavy chains were composed of VH regions derived from the VH2 (Q52) germline gene family and all used the same J4 gene segment. In addition, two of the anti-N light chains were composed of VK regions from the VK8 germline gene family and used the J1 gene segment. Since each anti-N hybridoma was derived from different mice immunized by different protocols, these results suggest that the murine immune response to the N, but not the M, human blood group antigen is restricted

The amelogenins are the predominant matrix proteins in developing enamel and are crucial for proper enamel mineralization. Transgenic mice were constructed in order to identify the segment of the amelogenin gene required for specific expression in enamel organ cells. A 3.5 kb fragment of the bovine X-chromosomal amelogenin gene that includes a TATA box, the transcription initiation site, and 32 bp of exon 1 was linked to the beta galactosidase gene and injected into fertilized mouse eggs. Newborn transgene positive mice expressed beta galactosidase activity in developing teeth treated with the chromogenic substrate Xgal. Foci of ameloblasts were positive in newborn mice; stain intensity and number of positive ameloblasts increased in 1-day and 2-day postnatal mice. Some of the adjacent stratum intermedium cells also were positive in the later stages. Targeting of the transgene to the enamel organ was specific; the only other cells observed to be positive were macrophages, which have endogenous beta galactosidase activity

Microfibrils having a diameter of 10-12 nm, found either in association with elastin or independently, are an important component of the extracellular matrix of many tissues. Because isolation of native proteins composing the microfibrils has proven difficult, information on structure/function relationships is limited. In order to extend our understanding of the 31-kDa microfibril-associated glycoprotein (MAGP), the bovine gene has been cloned and characterized and the protein has been expressed in a eukaryotic system. The compact coding portion of the gene is contained in 4.5 kbp of genomic DNA and does not appear to share any domain motifs with other known proteins. The size, amino acid composition, and sequence of the amino terminus of the secreted recombinant protein (rMAGP) all agree with values predicted by the nucleotide sequence of the cDNA used in the expression vector. The rMAGP reacts with a monospecific antibody prepared against a defined amino acid sequence of the natural molecule and reacts specifically with recombinantly produced tropoelastin, suggesting that rMAGP will be a useful reagent with which to study its interaction with other extracellular matrix components

The elastic properties of many tissues such as the lung, dermis, and large blood vessels are due to the presence of elastic fibers in the extracellular space. These fibers have been shown by biochemical and ultrastructural analysis to be composed of two distinct components, a more abundant amorphous component and a 10-12 nm microfibrillar component, which is located primarily around the periphery of the amorphous component. The protein elastin makes up the highly insoluble amorphous component and is responsible for the elastic properties. Elastin is found throughout the vertebrate kingdom and possesses an unusual chemical composition rich in glycine, proline, and hydrophobic amino acids, consonant with its characteristic physical properties. The 72-kDa biosynthetic precursor, tropoelastin, is secreted into the extracellular space where it becomes highly cross-linked into a rubber-like network through the activity of the copper-requiring enzyme lysyl oxidase. Analysis of the elastin gene has demonstrated that hydrophobic and cross-linking domains are encoded in separate exons and that there is significant alternative splicing, resulting in multiple isoforms of tropoelastin. The elastin gene promoter contains many potential binding sites for various modulating factors indicative of a complex pattern of transcriptional regulation. The microfibrils contain several proteins, including fibrillin, and probably act as an organizing scaffold in the formation of the elastin network. There appears to be a fibrillin gene family in which each protein contains multiple repeats of a motif previously found in epidermal growth factor and a second motif observed in transforming growth factor beta 1-binding protein. Mutations in the fibrillin gene located on human chromosome 15 have been strongly implicated as the cause of the Marfan syndrome

The use of recombinant human tropoelastin (rTE) and selected variants thereof as substrates for the assay of lysyl oxidase activity in vitro was explored. The possibility was also assessed that an insoluble elastin-like product could be generated from this elastin precursor in the absence of other macromolecules found associated with elastin in vivo. rTE was more efficiently oxidized by lysyl oxidase than the insoluble chick aorta elastin substrate conventionally used. Anionic amphiphilic elastin ligands strongly inhibited rTE oxidation consistent with the importance of electrostatic enzyme-substrate interactions previously noted with the insoluble elastin substrate. An rTE variant, rTE delta 26A, lacking the hydrophilic sequence coded by exon 26A, was a less effective substrate than rTE, largely due to an increase in Km, while the kinetic parameters for the oxidation of rTE delta 36, lacking the C-terminal polybasic sequence coded by exon 36, were quite similar to those for rTE. Incubation of rTE delta 26A with lysyl oxidase not only resulted in the generation of peptidyl alpha-aminoadipic-delta-semialdehyde and lysine-derived cross-linkages, but also yielded a product insoluble in hot 0.1 N NaOH, consistent with the properties of insoluble elastin. Thus, oxidation, cross-linking and insolubilization of elastin substrates by lysyl oxidase can occur in the absence of other macromolecules implicated as being involved in this process in vivo, although such macromolecules may be essential to obtain the proper alignment between tropoelastin units for specifically placed cross-linkages and optimally functional elastic fibers.