Head-to-head arrangement of murine type IV collagen genes

Collagen IV and basement membrane at the evolutionary dawn of metazoan tissues

The role of the cellular microenvironment in enabling metazoan tissue genesis remains obscure. Ctenophora has recently emerged as one of the earliest-branching extant animal phyla, providing a unique opportunity to explore the evolutionary role of the cellular microenvironment in tissue genesis. Here, we characterized the extracellular matrix (ECM), with a focus on collagen IV and its variant, spongin short-chain collagens, of non-bilaterian animal phyla. We identified basement membrane (BM) and collagen IV in Ctenophora, and show that the structural and genomic features of collagen IV are homologous to those of non-bilaterian animal phyla and Bilateria. Yet, ctenophore features are more diverse and distinct, expressing up to twenty genes compared to six in vertebrates. Moreover, collagen IV is absent in unicellular sister-groups. Collectively, we conclude that collagen IV and its variant, spongin, are primordial components of the extracellular microenvironment, and as a component of BM, collagen IV enabled the assembly of a fundamental architectural unit for multicellular tissue genesis.

DOI:http://dx.doi.org/10.7554/eLife.24176.001

The emergence of the diversity of multicellular animals involved cells joining together to form tissues and organs. The ‘glue’ that enabled the cells to work together is made of rope-like molecules called collagen, which assemble into scaffolds. These smart scaffolds tether proteins forming basement membranes that connect cells, provide strength to tissues, and transmit information that influences how the cells behave.

How did collagen evolve over millions of years to enable the ever-increasing complexity, size and diversity of animals? To investigate, Fidler, Darris, Chetyrkin et al. explored the tissues of the most ancient of currently living animals – the comb jellies and sponges. This revealed that among all the collagens that make up the human body, a type called collagen IV was a key innovation that enabled single celled organisms to evolve into multicellular animals. Collagen IV, as molecular glue, enabled the formation of a fundamental architectural unit of basement membrane and cells that allowed multicellular tissues and organs to evolve.

The findings presented by Fidler, Darris, Chetyrkin et al. pose questions about how collagen IV glues cells together, and how information is stored in the rope-like scaffolds to influence cell behavior. Understanding these processes could ultimately lead to the development of new treatments for diseases in which the collagen smart scaffolds play a key role, such as in kidney diseases and cancer.

DOI:http://dx.doi.org/10.7554/eLife.24176.002

The Wilms tumor gene, Wt1, maintains testicular cord integrity by regulating the expression of Col4a1 and Col4a2

Wt1 is specifically expressed in Sertoli cells in the developing testis. A previous study has demonstrated that Wt1 plays a critical role in maintaining the integrity of testicular cords. However, the underlying mechanism is unclear. In this study, we found that the laminin-positive basal lamina lining the testicular cords was fragmented and completely absent in some areas of Wt1(-/flox); Amh-Cre testes, indicating that the testicular cord disruption can be attributed to the breakdown of the basement membrane. To explore the molecular mechanism underlying this effect, we examined the expression of cell adhesion molecules (CAMs) and testicular cord basal lamina components by real-time RT-PCR, Western blotting, and immunostaining. Compared with control testes, the expression of CAMs (such as E-cadherin, N-cadherin, claudin11, occludin, beta-catenin, and ZO-1) was not obviously altered in Wt1(-/flox); Amh-Cre testes. However, the mRNA level of Col4a1 and Col4a2 was significantly decreased in Wt1-deficient testes. Immunostaining assays further confirmed that the collagen IV protein levels were dramatically reduced in Wt1(-/flox); Amh-Cre testes. Moreover, luciferase and point mutation analyses revealed that the Col4a1 and Col4a2 promoters were additively transactivated by WT1 and SOX9. Given this finding and previous results showing that SOX9 expression declines rapidly after Wt1 deletion, we conclude that the loss of Wt1 in Sertoli cells results in the downregulation of the important basal lamina component, which in turn causes the breakdown of the basal lamina and subsequent testicular cord disruption.

SRY-related HMG box 9 regulates the expression of Col4a2 through transactivating its enhancer element in mesangial cells

Accumulation of alpha1(IV) and alpha2(IV) collagen is one of the characteristic pathological changes in glomerulosclerosis. Although the Col4a2 gene is known to have a 0.3-kb critical enhancer element with the GAACAAT motif, which transcription factor binds and transactivates this motif has not been identified. In this study, we found that SRY-related HMG box 9 (SOX9) was bound to the GAACAAT motif in the Col4a2 enhancer in vitro and in vivo in mesangial cells. SOX9 strongly activated this enhancer when cotransfected with Col4a2 enhancer-promoter construct in mesangial cells and Swiss/3T3 cells. Mutation in the GAACAAT motif eliminated the activation by SOX9. Furthermore, transforming growth factor-beta (TGF-beta) treatment induced the expression of SOX9 and Col4a2, and a small interfering RNA against SOX9 reduced Col4a2 expression induced by TGF-beta treatment in mesangial cells. In vivo, we found that the expression of SOX9 was dramatically increased along with the expression of TGF-beta and Col4a2 in mouse nephrotoxic nephritis. These results indicate that SOX9 is essential for Col4a2 expression in mesangial cells and might be involved in the accumulation of alpha2(IV) collagen in experimental nephritis.

Basement membrane type IV collagen molecules in the choroid plexus, pia mater and capillaries in the mouse brain

We investigated the differential distribution of basement membrane type IV collagen a chains in the mouse brain by immunohistochemistry using a chain-specific monoclonal antibodies. Subendothelial basement membranes were found to contain alpha1 and alpha2 chains. Basement membranes surrounding smooth muscle cells on blood vascular walls were immunoreactive for alpha1 and alpha2 chains but not for alpha5 and alpha6 chains. Interestingly, the pia mater contained a thin basement membrane which was positive for alpha1, alpha2, alpha5, and alpha6 chains, suggesting that glia limitans superficialis coheres basement membranes containing [alpha1(IV)]2alpha2(IV) and [alpha5(IV)]2alpha6(IV) molecules. In contrast, capillaries always possessed thin basement membranes of [alpha1(IV)]2alpha2(IV) molecules. Cerebrospinal fluid is produced through filtration of blood at the choroid plexus, where two distinct basement membranes were detected by anti-al and anti-alpha2 antibodies. The subendothelial basement membrane appeared to consist of [alpha1(IV)]2alpha2(IV) molecules, whereas the subependymal basement membrane in the choroid plexus was strongly positive for alpha3, alpha4, and alpha5 chains, indicating that the filtering unit was composed of alpha3(IV)alpha4(IV)alpha5(IV) molecules. That the specific localizations of these molecules are shared by renal glomeruli and the choroid plexus leads us to hypothesize that the supramolecular network containing alpha3(IV) alpha4(IV)alpha5(IV) molecules may function as a permeability selective barrier.

Insertional mutation of the collagen genes Col4a3 and Col4a4 in a mouse model of Alport syndrome

Mice homozygous for the transgenic insertion in line OVE250 exhibit severe progressive glomerulonephritis. Ultrastructural changes in the glomerular basement membrane (GBM) at 2 weeks of age resemble those in Alport syndrome. The transgenic insertion site was mapped by FISH to mouse chromosome 1 close to Pax3. Genetic and molecular analyses identified a deletion of genomic DNA at the transgene insertion site. Exons 1 through 12 of the collagen IV gene Col4a4, exons 1 and 2 of the adjacent Col4a3 gene, and the intergenic promoter region are deleted. Transcripts of Col4a3 and Col4a4 are undetectable in mutant kidney, and both proteins are missing from the GBM. Persistent cellular proliferation in mutant kidneys suggests that interaction with the extracellular matrix may be important for cell maturation. Evolutionarily conserved sequence elements in the promoter regions of human and mouse Col4a3 and Col4a4 include a 19-bp element that was tandemly duplicated in the human lineage and a CTC box element common to several genes encoding extracellular matrix proteins. This new animal model of Alport syndrome, Col4Delta3-4, lacks both alpha3 and alpha4 chains of collagen IV and exhibits an earlier disease onset than mice lacking alpha3 only.

Structure and mapping of the G protein gamma3 subunit gene and a divergently transcribed novel gene, gng3lg

The mammalian nervous system is rich in signaling mediated by heterotrimeric (alphabetagamma) G proteins. As an initial step to define the roles that particular gamma subunit types play in signaling, we have begun to clone and characterize those genes that encode gamma subunits enriched within neural tissue. In the present study, we have isolated and characterized the mouse gamma3 subunit gene (Gng3). The gamma3 subunit is expressed abundantly in the brain and at low levels in testes. Gng3 is composed of three exons spanning approximately 1.4 kb. A comparison of Gng3 with the gene structure for five other gamma subtypes indicates that although these proteins are diverse at the amino acid level, their exon-intron boundaries are conserved. Sequence analysis of the 5' flanking region of Gng3 revealed the presence of a novel gene, the gamma3 linked gene (Gng3lg). Gng3 and Gng3lg are organized in a head-to-head fashion with major transcription initiation sites separated by approximately 133 bp. Sequence analysis of a Gng3lg cDNA clone revealed an open reading frame encoding a 410-amino-acid protein of unknown function. Gng3lg transcripts are expressed in a variety of tissues including both brain and testes. Using an interspecific backcross panel, we localized both Gng3 and Gng3lg to the same locus on chromosome 19. The orientation, close proximity, and expression pattern of these two genes raise the distinct possibility that shared regulatory elements are used to control their expression.

Identification and characterization of a novel transcriptional silencer in the human collagen type IV gene COL4A2

Collagen type IV [alpha 1(IV)2 alpha 2(IV)] is the basic structural component of all basement membranes. The two subunit genes COL4A1 and COL4A2 are found closely linked in the human and murine genomes and are transcribed divergently from a common promoter. Previously, activating elements had been detected within both genes which are indispensable for efficient transcription. An additional negative regulatory element has now been identified within the third intron of the COL4A2 gene which is able to inhibit transcription of both COL4 genes from their shared promoter, as well as the nonrelated herpes simplex virus thymidine kinase promoter. The element exerts its inhibitory effect largely independently from its relative orientation and distance from the initiation site of transcription. Therefore, the element represents a silencer which is named the "COL4 silencer." The minimal functional silencer could be narrowed down by deletion mapping to a sequence element located within intron 3 of the COL4A2 gene. This motif is specifically recognized by a nuclear protein, named "SILBF," and the binding site of which was determined by footprinting assays. Mutation studies and deletion analysis proved that the presence of this sequence element and its interaction with SILBF is not only essential but also sufficient for the silencing function. We assume that the COL4 silencer plays an important role in the control of overall expression and the balance of divergent transcription of both COL4 genes.

Homologs of genes and anonymous loci on human chromosome 13 map to mouse chromosomes 8 and 14

To enhance the comparative map for human Chromosome (Chr) 13, we identified clones for human genes and anonymous loci that cross-hybridized with their mouse homologs and then used linkage crosses for mapping. Of the clones for four genes and twelve anonymous loci tested, cross-hybridization was found for six, COL4A1, COL4A2, D13S26, D13S35, F10, and PCCA. Strong evidence for homology was found for COL4A1, COL4A2, D13S26, D13S35, and F10, but only circumstantial homology evidence was obtained for PCCA. To genetically map these mouse homologs (Cf10, Col4a1, Col4a2, D14H13S26, D8H13S35, and Pcca-rs), we used interspecific and intersubspecific mapping panels. D14H13S26 and Pcca-rs were located on the distal portion of mouse Chr 14 extending by approximately 30 cM the conserved linkage between human Chr 13 and mouse Chr 14, assuming that Pcca-rs is the mouse homolog of PCCA. By contrast, Cf10, Col4a1, Col4a2, and D8H13S35 mapped near the centromere of mouse Chr 8, defining a new conserved linkage. Finally, we identified either a closely linked sequence related to Col4a2, or a recombination hot-spot between Col4a1 and Col4a2 that has been conserved in humans and mice.

Differential effects of DNA-binding proteins on bidirectional transcription from the common promoter region of human collagen type IV genes COL4A1 and COL4A2

Expression of the heterotrimeric collagen IV (alpha 1(IV))2 alpha 2(IV) is essential for the structural integrity and functional properties of basement membranes. The genes COL4A1 and COL4A2 coding for both subunits are located close to each other on the same chromosome and are transcribed from a common bidirectional promoter element. Binding of at least three different nuclear proteins could be detected within this promoter, a CCAAT-binding protein, Sp1 and a newly identified factor, designated 'CTCBF'. Mutagenesis of binding sites proved that these factors are essential for the efficient transcription of both genes, but revealed differential gene-specific effects. Therefore, the common promoter region of collagen IV does not represent an equally functional bidirectional element, but may be better understood as two overlapping gene-specific promoters with shared elements.

Evolution of collagen IV genes from a 54-base pair exon: a role for introns in gene evolution

The exon structure of the collagen IV gene provides a striking example for collagen evolution and the role of introns in gene evolution. Collagen IV, a major component of basement membranes, differs from the fibrillar collagens in that it contains numerous interruptions in the triple helical Gly-X-Y repeat domain. We have characterized all 47 exons in the mouse alpha 2(IV) collagen gene and find two 36-, two 45-, and one 54-bp exons as well as one 99- and three 108-bp exons encoding the Gly-X-Y repeat sequence. All these exons sizes are also found in the fibrillar collagen genes. Strikingly, of the 24 interruption sequences present in the alpha 2-chain of mouse collagen IV, 11 are encoded at the exon/intron borders of the gene, part of one interruption sequence is encoded by an exon of its own, and the remaining interruptions are encoded within the body of exons. In such "fusion exons" the Gly-X-Y encoding domain is also derived from 36-, 45-, or 54-bp sequence elements. These data support the idea that collagen IV genes evolved from a primordial 54-bp coding unit. We furthermore interpret these data to suggest that the interruption sequences in collagen IV may have evolved from introns, presumably by inactivation of splice site signals, following which intronic sequences could have been recruited into exons. We speculated that this mechanism could provide a role for introns in gene evolution in general.

Regulation of divergent transcription of the genes coding for basement membrane type IV collagen

The genes coding for the two polypeptide chains, alpha 1(IV) and alpha 2(IV), which form together the molecule of the basement membrane type IV collagen, were found to have a special and unusual genomic arrangement. The two genes are very closely linked, they are transcribed in opposite directions, and they apparently use a common and bidirectional promoter with a length of 127 bp. This region is characterized by a symmetrical arrangement of typical elements and by the palindromic structure of the sequence. In accordance with the symmetry of the promoter itself, a symmetrical organization of sequence motifs (SP1, CCAAT) was also observed in flanking regions. For the promoter and the flanking regions we could detect specific binding of nuclear factors that indicates their involvement in transcriptional activation. This suggests that the intrinsic symmetry of the type IV collagen promoter and its flanking regions may be a structural prerequisite for its bidirectional function. In transient gene expression systems no significant activity of the type IV collagen promoter was observed in either direction. This implies that additional enhancing elements are essential for the efficient and tissue-specific transcription of both type IV collagen genes. The screening for such controlling elements within the alpha 1(IV) and the alpha 2(IV) gene led to the observation that the transcription in direction of the alpha 2(IV) gene is activated by an element located in the first intron of the alpha 2 gene. Its enhancing effect is strictly dependent on the intact genomic structure of this region. Alternation of orientation and distance to the promoter destroys its activity completely. This element, located about 100-600 bp downstream from the start site of alpha 2(IV) transcription, seems to form a synergistically acting unit with the common promoter, essential for transcriptional activity in alpha 2 direction. We have not found additional enhancing elements in other regions of both genes. Explanations for the discrepancy with previous data, which define an enhancing element within the first intron of the alpha 1(IV) gene of mouse, are only speculative at present.