Regular location of exon starts in collagen I and VII genes with periods comparable to nucleosome repeat lengths

Wavelet transform analysis revealed quasiperiodicity of exon starts in the genes for collagens of types I and VII. In the regions coding for the fibrillar part of the protein, the average sum length of an exon and the following intron was ～165 nt, i.e. close to the minimal nucleosome repeat length. Such quasiperiodic segments comprising 2–5 contiguous exon+intron pairs of similar length encompassed more than 50% of exons making the fibrillar part. We also observed regular disposition of exon starts in the nonfibrillar part of collagen VII, but with a different period of 227 nt.     

Mutual disposition of nucleosomes and exons differs from common genome pattern at DNA segments containing periodic nucleotide sequences

Correlation was observed between DNA segments characterized by periodic patterns of nucleotides and nucleosome DNA binding sites predicted by the profiles of local DNA flexibility. Exons of human type I and VII collagen genes loci have been chosen as a sample set of periodic DNA segments. It was pointed that short periodic exons coding fibrillar part of these proteins are localized near borders of the DNA sequence that binds the histone core. One of the borders of exon and of this sequence coincide as a rule. In non-fibrillar parts of collagen genes, exons (longer on average) dispose, in contrast, in any place of the DNA sequence bound to the nucleosome core.     

Statistical characteristics of eukaryotic intron database

A database called eukaryotic intron database (EID) was developed based on the data from GenBank.Studies on the statistical characteristics of EID show that there were 103,848 genes,478,484 introns,and 582,332 exons,with an average of 4.61 introns and 5.61 exons per gene.Introns of 40-120 nt in length were abundant in the database.Results of the statistical analysis on the data from nine model species showed that in eukaryotes,higher species do not necessarily have more introns or exons in a gene than lower species.Furthermore,characteristics of EID,such as intron phase,distribution of different splice sites,and the relationship between genome size and intron proportion or intron density,have been studied.     

Alpha 1 type IV collagen gene evolved differently from fibrillar collagen genes

Type IV collagen is a major structural component in basement membranes. It is considerably different from the fibrillar collagens, types I-III. For example, unlike fibrillar collagens, the triple helical domain of type IV collagen is frequently interrupted by nonhelical regions. In this report, we demonstrate several overlapping genomic clones which cover most of the mouse alpha 1(IV) chain. Electron microscopic analysis of R-loops revealed that there were at least 28 exons within 35 kilobases of the gene segment. The sizes of six exons were determined by DNA sequence analysis to be 81, 178, 134, 73, 129, and 213 base pairs. These sizes do not appear to be related to the 54-base pair coding unit which is characteristic of fibrillar collagen exons, suggesting that the alpha 1 type IV collagen gene evolved differently from the fibrillar collagen genes.     

Exon structure of a mannose-binding protein gene reflects its evolutionary relationship to the asialoglycoprotein receptor and nonfibrillar collagens

Cloned cDNAs encoding mannose-binding proteins isolated from rat liver have been used to isolate one of the genes encoding this group of proteins. This gene, which encodes the minor form of binding protein (designated MBP-A), has been characterized by sequence analysis. The protein-coding portion of the mRNA for the MBP-A is encoded by four exons separated by three introns. The NH2-terminal, collagen-like portion of the protein is encoded by the first two exons. These exons resemble the exons found in the genes for nonfibrillar collagens in that the intron which divides them is inserted between the first two bases of a glycine codon and the exons do not have the 54- or 108-base pair lengths characteristic of fibrillar collagen genes. The carbohydrate-binding portion of MBP-A is encoded by the remaining two exons. This portion of the protein is homologous to the carbohydrate-recognition domain of the hepatic asialoglycoprotein receptor, which is encoded by four exons. It appears that the three COOH-terminal exons of the asialoglycoprotein receptor gene have been fused into a single exon in the MBP-A gene. The organization of the MBP-A gene is very similar to the arrangement of the gene encoding the highly homologous pulmonary surfactant apoprotein, although one of the intron positions is shifted by a single amino acid. The 3' end of a mannose-binding protein pseudogene has also been characterized.     

SSCP and segregation analysis of the human type X collagen gene (COL10A1) in heritable forms of chondrodysplasia.

Type X collagen is a homotrimeric, short chain, nonfibrillar collagen that is expressed exclusively by hypertrophic chondrocytes at the sites of endochondral ossification. The distribution and pattern of expression of the type X collagen gene (COL10A1) suggests that mutations altering the structure and synthesis of the protein may be responsible for causing heritable forms of chondrodysplasia. We investigated whether mutations within the human COL10A1 gene were responsible for causing the disorders achondroplasia, hypochondroplasia, pseudoachondroplasia, and thanatophoric dysplasia, by analyzing the coding regions of the gene by using PCR and the single-stranded conformational polymorphism technique. By this approach, seven sequence changes were identified within and flanking the coding regions of the gene of the affected persons. We demonstrated that six of these sequence changes were not responsible for causing these forms of chondrodysplasia but were polymorphic in nature. The sequence changes were used to demonstrate discordant segregation between the COL10A1 locus and achondroplasia and pseudoachondroplasia, in nuclear families. This lack of segregation suggests that mutations within or near the COL10A1 locus are not responsible for these disorders. The seventh sequence change resulted in a valine-to-methionine substitution in the carboxyl-terminal domain of the molecule and was identified in only two hypochondroplasic individuals from a single family. Segregation analysis in this family was inconclusive, and the significance of this substitution remains uncertain.     

Nucleolin gene organization in rodents: highly conserved sequences within three of the 13 introns

The complete nucleotide (nt) sequence of the rat nuc gene encoding nucleolin, the major nucleolar-specific protein in eukaryotic exponentially growing cells, is compared with the corresponding locus recently characterized in mouse. [Bourbon et al., J. Mol. Biol. 200 (1988) 627-638]. In both murine species the genomic organization has been strikingly conserved during evolution, i.e., the coding region extends over 9 kb and is split into 14 exons, encoding a 712-amino acid protein. Moreover, all the exon-intron junction positions were strictly maintained during evolution. More unexpectedly, this analysis revealed that several introns contain highly conserved sequence elements of about 120 nt. The nt sequence of the homologous locus isolated from a Chinese hamster genomic clone established that these regions were under unusually high selective constraints (84-96% identity between the hamster and murine nuc genes) and, although they do not contain open reading frames, they surprisingly appear to be more conserved than most of the exons, suggesting that they play an important role. Such an element of 130 nt presents features of known genes transcribed by RNA polymerase III. Furthermore, in the rat nuc pre-mRNA the 5'- and 3'-end regions of the last intron are fully complementary over 16 nt, and so are predicted to be included in a prominent stem structure. Moreover, an homologous RNA stem structure can be derived from the mouse sequence, including two compensatory nt changes. As the secondary structure would occlude the canonical sequences required for the proper excision of this intron in both murine species, this remarkable finding could be relevant to the regulation of the nuc gene expression at the RNA processing level.     

Multiple denaturational transitions in fibrillar collagen

The heat denaturation of pepsinized bovine nonfibrillar and fibrillar collagen was studied by differential scanning calorimetry. For fibrillar preparations that had been rapidly precipitated with stirring at low ionic strength, then resuspended at physiological ionic strength, multiple denaturational transitions were observed. At heating rates of 10°C/min, melting endotherms occurred at about 44, 50, 53, and 57°C. Fibrillar collagen that was slowly gelled without stirring at physiological ionic strength exhibited a similar series of endotherms, but the lower melting transitions were less conspicuous. In contrast, nonfibrillar bovine collagen in acidic solution showed only a single denaturational transition at 40°C. Nonfibrillar solutions at pH 7, to which inhibitors of fibrillogenesis were added, showed a major endotherm as high as 46°C. These results suggest that reconstituted fibrillar collagen contains a heterogeneous fibril population, possibly including molecules in a nonfibrillar state. It was proposed that the multiple melting endotherms of such preparations were due to sequential melting of molecular and fibril classes, each with a distinct melting temperature. The fibrillar classes may represent three or more types of banded and nonbanded species that differ from each other in packing order, collagen concentration, and possibly also in fibril width and level of cross-linking.     

The Lewy Body in Parkinson’s Disease and Related Neurodegenerative Disorders

The histopathological hallmark of Parkinson’s disease (PD) is the presence of fibrillar aggregates referred to as Lewy bodies (LBs), in which α-synuclein is a major constituent. Pale bodies, the precursors of LBs, may serve the material for that LBs continue to expand. LBs consist of a heterogeneous mixture of more than 90 molecules, including PD-linked gene products (α-synuclein, DJ-1, LRRK2, parkin, and PINK-1), mitochondria-related proteins, and molecules implicated in the ubiquitin–proteasome system, autophagy, and aggresome formation. LB formation has been considered to be a marker for neuronal degeneration because neuronal loss is found in the predilection sites for LBs. However, recent studies have indicated that nonfibrillar α-synuclein is cytotoxic and that fibrillar aggregates of α-synuclein (LBs and pale bodies) may represent a cytoprotective mechanism in PD.     

Structural constraints on the evolution of the collagen fibril: convergence on a 1014-residue COL domain

Type I collagen is the fundamental component of the extracellular matrix. Its α1 gene is the direct descendant of ancestral fibrillar collagen and contains 57 exons encoding the rod-like triple-helical COL domain. We trace the evolution of the COL domain from a primordial collagen 18 residues in length to its present 1014 residues, the limit of its possible length. In order to maintain and improve the essential structural features of collagen during evolution, exons can be added or extended only in permitted, non-random increments that preserve the position of spatially sensitive cross-linkage sites. Such sites cannot be maintained unless the twist of the triple helix is close to 30 amino acids per turn. Inspection of the gene structure of other long structural proteins, fibronectin and titin, suggests that their evolution might have been subject to similar constraints.     

Phosphorylation of H2AX histone as indirect evidence for double-stranded DNA breaks related to the exchange of nuclear proteins and chromatin remodeling in Chara vulgaris spermiogenesis

Phosphorylation of H2AX histone results not only from DNA damage (caused by ionizing radiation, UV or chemical substances, e.g. hydroxyurea), but also regularly takes place during spermiogenesis, enabling correct chromatin remodeling. Immunocytochemical analysis using antibodies against H2AX histone phosphorylated at serine 139 indirectly revealed endogenous double-stranded DNA breaks in Chara vulgaris spermatids in mid-spermiogenesis (stages V, VI and VII), when protamine-type proteins appear in the nucleus. Fluorescent foci were not observed in early (stages I-IV) and late (VIII-X) spermiogenesis, after replacement of histones by protamine-type proteins was finished. A similar phenomenon exists in animals. Determination of the localization of fluorescent foci and the ultrastructure of nuclei led to the hypothesis that DNA breaks at stage V, when condensed chromatin adheres to the nuclear envelope. This is transformed into a net-like structure during stage VI, probably allowing chromosome repositioning to specific regions in the mature spermatozoid. However, at stages VI and VII, DNA breaks are necessary for transformation of the nucleosomal structure into a fibrillar and finally the extremely condensed status of sleeping genes at stage X.