Molecular structure of a novel cholesterol-responsive A subclass ABC transporter,ABCA9

We recently identified a novel ABC A subclass transporter, ABCA6, in human macrophages. Here, we report the molecular cloning of an additional ABC A subfamily transporter from macrophages denoted ABCA9. The identified coding sequence is 4.9 kb in size and codes for a 1624 amino acid protein product. In accordance with the proposed nomenclature, the novel transporter was designated ABCA9. The putative full-length ABC transporter polypeptide consists of two transmembrane domains and two nucleotide binding folds and thus conforms to the group of full-size ABC transporters. We identified alternative ABCA9 mRNA variants in human macrophages that predict the existence of three truncated forms of the novel transporter. Among the human ABC A subfamily transporters, ABCA9 exhibits the highest amino acid sequence homology with ABCA8 (72%) and ABCA6 (60%), respectively. The striking amino acid sequence similarity between these transporter molecules supports the notion that they represent an evolutionary more recently emerged subgroup within the family of ABC A transporters, which we refer to as "ABCA6-like transporters." ABCA9 mRNA is ubiquitously expressed with the highest mRNA levels in heart, brain, and fetal tissues. Analysis of the genomic structure revealed that the ABCA9 gene consists of 39 exons that are located within a genomic region of approximately 85 kb size on chromosome 17q24.2. In human macrophages, ABCA9 mRNA is induced during monocyte differentiation into macrophages and suppressed by cholesterol import indicating that ABCA9, like other known ABC A subfamily transporters, is a cholesterol-responsive gene. Based on this information, ABCA9 is likely involved in monocyte differentiation and macrophage lipid homeostasis.     

Mitochondrial DNA in the Bark Weevils: Size, Structure and Heteroplasmy

Mitochondrial DNA of higher animals has been described as an example of extreme efficiency in genome structure and function. Where exceptionally large size molecules have been found (greater than 20 kb), most have occurred as rare variants within a species, suggesting that these variants arise infrequently and do not persist for long periods in evolutionary time. In contrast, all individuals of at least three species of bark weevil (Curculionidae: Pissodes) possess a mitochondrial genome of unusually large size (30-36 kb). The molecule owes its large size to a dramatically enlarged A + T-rich region (9-13 kb). Gene content and order outside of this region appear to be identical to that found in Drosophila. A series of 0.8-2.0-kb repeated sequences occur adjacent to the large A + T rich region and have perhaps played a role in the generation of the large size as well as an unprecedented frequency of size variant heteroplasmy. Every weevil sampled in all three species (n = 219) exhibits anywhere from two to five distinct size classes of mtDNA. The persistence of this large amount of size polymorphism through two speciation events combined with the abundant size variation within individuals suggests that these molecules may not be subject to strong selection for small overall size and efficiency of replication. This pattern of variation contrasts strongly with the conservation of gene content and arrangement in the coding region of the molecule.     

Single strand-containing replicating molecules of circular mitochondrial DNA

Mitochondrial DNAs (mtDNAs) from Chang rat solid hepatomas and Novikoff rat ascites hepatomas were examined in the electron microscope after preparation by the aqueous and by the formamide protein monolayer techniques. MtDNAs from both tumors were found to include double-forked circular molecules with a form and size suggesting they were replicative intermediates. These molecules were of two classes. In molecules of one class, all three segments were apparently totally double stranded. Molecules of the second class were distinguished by the fact that one of the segments spanning the region between the forks in which replication had occurred (the daughter segments) was either totally single stranded, or contained a single-stranded region associated with one of the forks. Daughter segments of both totally double-stranded and single strand-containing replicating molecules varied in length from about 3 to about 80% of the circular contour length of the molecule. Similar classes of replicating molecules were found in mtDNA from regenerating rat liver and chick embryos, indicating them to be normal intermediates in the replication of mtDNA All of the mtDNAs examined included partially single-stranded simple (nonforked) circular molecules. A possible scheme for the replication of mtDNA is presented, based on the different molecular forms observed     

Size classes of replication units in DNA from sea urchin embryos

Sea urchin DNA containing replication structures was isolated from two to four cell stage and blastula stage embryos, and examined by electron microscopy. In addition to the expected eye forms, we also observed molecules with large internal single-stranded gaps. Such structures were not present in DNA devoid of replicating molecules such as that isolated from sea urchin sperm. When the size of eye forms and interbubble distances between the two stages were compared, there was no detectable difference. In both stages, we observed two distinct size classes of bubbles and of interbubble distances. In the case of bubble sizes, the smaller size class was comprised of clustered microbubbles that ranged from 200 base pairs to 1 Kilobase (kb) with a mean of 432 base pairs. The large eye forms measured 1--35 kb with a mean of 6.8 kb. Interbubble distances also yielded two distinct populations, with the smaller class ranging from 400 base pairs to 2.3 kb (mean = 1.1 kb) and the larger population ranging from 2.8 to 36 kb (mean = 10.9 kb). Although other possibilities cannot be entirely excluded, the data support the contention that a substantial fraction of the larger eye-form population arises from the fusion of the clustered microbubbles.     

Sequence-specific fragmentation of macronuclear DNA in a holotrichous ciliate

Macronuclear DNA from the protozoan G. chattoni, a holotrichous ciliate, was analyzed. Most, if not all, of the macronuclear DNA is subchromosomal, ranging in size from above 100 kb down to 2.1 kb, with molecules in the lower molecular weight range being resolvable by gel electrophoresis into reproducible, specific, discrete size classes. A prominent class of linear 9.3 kb molecules consists of single free rRNA genes. Upon denaturation and partial renaturation, a high percentage of total macronuclear DNA was found as single-stranded circles. Sequence analysis showed that a minimum of 38 tandem repeats of the sequence CCCCAA is present in inverted orientation at each end of most or all Glaucoma macronuclear DNA molecules, including the rDNA. This sequence must therefore be recognized during site-specific fragmentation of chromosomes in macronuclear development.     

The Subtelomeric Y'' Repeat Family in Saccharomyces Cerevisiae: An Experimental System for Repeated Sequence Evolution

The subtelomeric Y' repeated sequence families in two divergent strains of the yeast Saccharomyces cerevisiae have been characterized in terms of copy number, location and restriction site differences. The strain YP1 has 26 to 30 Y's that fall into two previously described, long (6.7 kb) and short (5.2 kb), size classes. These Y's reside at 19 of the 32 chromosome ends and are concentrated in the higher molecular weight chromosomes. Five ends contain tandem arrays, each of which has only one size class of Y's. There is restriction site homogeneity among the Y's of YP1 even between size classes. The Y's of strain Y55 contrast sharply with the Y's of YP1 in terms of copy number, location and sequence differences. There are 14 to 16 Y's, both long and short, most of which are found at different chromosome ends than those of YP1. None of these are tandemly arrayed. Four to six of the Y's appear degenerate in that they have homology with a telomere distal end Y' probe but no homology with sequences at the telomere proximal end. The majority of the Y55 Y's have the same restriction sites as in YP1. Despite the conservation of restriction sites among Y's, a great deal of restriction fragment length heterogeneity between the strains is observed. The characterized Y' repeated sequence families provide an experimental system in which repeated sequence interactions and subsequent evolution can be studied.     

X and Y chromosomal ribosomal DNA of Drosophila: comparison of spacers and insertions.

In Drosophila melanogaster, the genes coding for 18S and 28S ribosomal RNA (rDNA) are clustered at one locus each on the X and the Y chromosomes. We have compared the structure of rDNA at the two loci. The 18S and 28S rRNAs coded by the X and Y chromosomes are very similar and probably identical (Maden and Tartof, 1974). In D. melanogaster, many rDNA repeating units are interrupted in the 28S RNA sequence by a DNA region called the insertion. There are at least two sequence types of insertions. Type 1 insertions include the most abundant 5 kilobase (kb) class and homologous small (0.5 and 1 kb) insertions. Most insertions between 1.5 and 4 kb have no homology to the 5 kb class and are identified as type 2 insertions. In X rDNA, about 49% of all rDNA repeats have type 1 insertions, and another 16% have type 2 insertions. On the Y chromosome, only 16% of all rDNA repeats are interrupted, and most if not all insertions are of type 2.rDNA fragments derived from the X and Y chromosomes have been cloned in E. coli. The homology between the nontranscribed spacers in X and Y rDNA was studied with cloned fragments. Stable heteroduplexes were found which showed that these regions on the two chromosomes are very similar.The evolution of rDNA in D. melanogaster might involve genetic exchange between the X and Y chromosomal clusters with restrictions on the movement of type 1 insertions to the Y chromosome.     

A deletion mutant of L-A double-stranded RNA replicates like M1 double-stranded RNA.

X double-stranded RNA (dsRNA) is a 0.52-kilobase dsRNA molecule that arose spontaneously in a nonkiller strain of Saccharomyces cerevisiae originally containing L-A and L-BC dsRNAs (L-BC is the same size as L-A but shares no homology with it). X hybridized with L-A, and direct RNA sequencing of X showed that the first 5' 25 base pairs (of the X positive strand) and at least the last 110 base pairs of the 3' end were identical to the ends of L-A dsRNA. X showed cytoplasmic inheritance and, like M1, was dependent on L-A for its maintenance. X was encapsidated in viruslike particles whose major coat protein was provided by L-A (as is true for M1), and X was found in viruslike particles with one to eight X molecules per particle. This finding confirms our "head-full replication" model originally proposed for M1 and M2. Like M1 or M2, X lowers the copy number of L-A, especially in a ski host. Surprisingly, X requires many chromosomal MAK genes that are necessary for M1 but not for L-A.     

Some physicochemical properties of rice mitochondrial DNA

Summary Certain physicochemical properties of rice mitochondrial DNA (mtDNA) were determined. Certain low-molecular-weight mtDNA bands were found in addition to the major mtDNA band. Rice mtDNA appeared in the electron microscope as a collection of linear molecules with heterogeneous length in the range of 1–156 kb. The major distribution area was 60–105 kb. A small fraction (less than 5%) of rice mtDNA was found in the form of a circular molecule. Some molecules had the appearance of being supercoiled. Replication fork structures were found in both circular and linear mtDNA molecules. In one rice species, Jin Nante, 15 different circular molecules were found. Rice mtDNA was digested with different restriction enzymes. The total molecular weight of rice mtDNA was calculated to be about 300 kb according to the data of restriction enzyme digestion and electron microscopy.     

Three ATP-binding cassette transporter genes,Abca14, Abca15, and Abca16, form a cluster on mouse Chromosome 7F3

We have identified and cloned three mouse genes that belong to the ABCA subfamily of ATP-binding cassette (ABC) transporters. These three genes are arranged in a tandem head-to-tail cluster spanning about 300 kb on mouse Chromosome (Chr) 7F3. Phylogenetic analysis indicates that although the three genes are related to human and mouse ABCA3, they are not orthologs of any of the current list of 48 human ABC genes and were, therefore, named Abca14, Abca15, and Abca16. The coding region of each gene is split into 31 exons, has an open reading frame of more than 1600 amino acids, and encodes a full transporter molecule with two nucleotide-binding folds (NBF) and two transmembrane domains (TMD). All three genes are predominantly expressed in testis, which suggests that they may perform special functions in testicular development or spermatogenesis. Interestingly, the human genome contains only fragments (less than ten exons) of at least two different ABC genes in the syntenic region on Chromosome 16p12 that are scattered among other, unrelated genes and are not capable of coding functional ABC transporters.(Zhang-qun Chen and Tarmo Annilo) These authors contributed equally to this study.Sequence data from this article have been deposited with the DDBJ/EMBL/GenBank Data Libraries under accession numbers AY243470–AY243472.     

Dynamics of DNA molecules in gel studied by fluorescence microscopy

The dynamics of individual DNA molecules in a thin gel were studied with fluorescence microscopy. Driven by an electric field, molecules hooked around isolated obstacles and became extended. By analyzing molecular images, we identified the reptation tube and primitive chain. When the field was turned off, the molecules relaxed. The relaxation time tau1 and primitive chain length at equilibrium depend on N, the size of the molecule in base pairs, consistently with reptation theory. Using five yeast chromosomal DNAs ranging in size from 245 kb to 980 kb, we found that: These results constitute a way of sizing individual DNA molecules by imaging rather than by gel electrophoresis.     

Isolation of oligo(U)-containing heterogeneous nuclear RNA from control and 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole-treated HeLa cells

Most (54–79%) of the heterogeneous nuclear RNA (hnRNA) which contains oligo(U) sequences was specifically retained on columns of poly(A) Sepharose and separated from hnRNA which lacked oligo(U) sequences. The isolation of oligo(U)-containing hnRNA was maximized by treating the hnRNA with HCHO prior to chromatography. This permitted an initial characterization of the oligo(U)-containing hnRNA. Experiments suggest that HCHO denatured the hnRNA and rendered the oligo(U) sequences accessible to poly(A) Sepharose. In denatured hnRNA, the percentage of molecules which contained an oligo(U) sequence increased with the size of the hnRNA; 32–57% of the large hnRNA [8–13 kilobases (kb) long] contained an oligo(U) sequence while only 11–14% of the 2-kb-long hnRNA contained an oligo(U) sequence. The number of oligo(U) sequences per molecule was also measured in denatured hnRNA of varying length. While the largest hnRNA class analyzed (13 kb) was found to contain the highest percentage of oligo(U)-containing molecules (57%), the 8- and 2-kb-long hnRNA fractions contained a greater total number of oligo(U)-containing molecules. The percentage of hnRNA molecules which contained an oligo(U) sequence, the number of oligo(U) sequences per molecule, and the size of the oligo(U) sequence were similar in both control hnRNA and the fraction of hnRNA (~30%) which is resistant to inhibition by 5,6-dichloro-1-β-d-ribofuranosylbenzimidazole.     

Size conversion of a linear plasmid in the relapsing fever agent Borrelia duttonii

Borreliae have genomes composed of both linear and circular replicons. We have characterized the organization of linear DNA molecules from the Borrelia duttonii strain Ly. It contains a linear one megabase chromosome and 12 linear plasmids of 11 to 200 kb in size. A variant of the strain obtained after successive in vitro cultivation in BSKII medium had a 69 kb molecule instead of the 44 kb linear plasmid. No detectable differences in the growth rates and cellular structures were found. Southern hybridization using the vsp33 gene sequence from Borrelia hermsii as a probe showed that both plasmids (69 and 44 kb molecules) contained a similar part of the sequence. The spirochetes of the parental strain cause erythrocytes to aggregate in mice blood, but the variant did not form such aggregates and seemed to have lost its infectivity in mice. Size conversion of the linear plasmid may be associated with the host-parasite relationship in mammals.