Changes in mRNA length accompany translational regulation of the somatic and testis-specific cytochrome c genes during spermatogenesis in the mouse

The mouse testis contains two isotypes of cytochrome c, which differ in 14 of 104 amino acids: cytochrome cs is present in all somatic tissues and cytochrome cT is testis specific. The regulation of cytochrome cS and cytochrome cT gene expression during spermatogenesis was examined by Northern blot analysis using specific cDNA probes. Total RNA was isolated from adult tissues, enriched germinal cell populations and polysomal gradients of total testis and isolated germinal cells. Three cytochrome cS mRNAs were detected averaging 1.3 kb, 1.1 kb and 0.7 kb in all tissues examined; an additional 1.7 kb mRNA was observed in testis. Isolated germinal cells through prepuberal pachytene spermatocytes contained only the three smaller mRNAs; the 1.7 kb mRNA was enriched in round spermatids. All three smaller cytochrome cS mRNAs were present on polysomes; the 1.7 kb mRNA was non-polysomal. Cytochrome cT mRNA of 0.6-0.9 kb was detected in testis; mRNA levels were low in early spermatogonia and peaked in prepuberal pachytene spermatocytes. In adult pachytene spermatocytes, a subset of the cytochrome cT mRNAs, 0.7-0.9 kb, was present on polysomes; a shortened size class, 0.6-0.75 kb, was non-polysomal. A distinct, primarily non-polysomal, cytochrome cT 0.7 kb mRNA was present in round spermatids. These results indicate that (1) both cytochrome cS and cytochrome cT mRNAs are present in early meiotic cells, (2) a 1.7 kb cytochrome cS mRNA is post-meiotically expressed and non-polysomal and (3) cytochrome cS and cytochrome cT mRNAs are each developmentally and translationally regulated during spermatogenesis.     

Structural organization of the mouse lactoferrin gene.

The complete structure of the mouse lactoferrin gene is presented. Mouse lactoferrin (mLF) is encoded by a single copy gene of approximately 30 kilobases (kb) in size. The gene is organized into 17 exons separated by 16 introns. The exons range in size from 48 base pairs (bp) to 190 bp whereas the introns range from 0.2 kb to 4.3 kb. Structural analysis of the mouse lactoferrin gene reveals that this gene shares a similar intron-exon distribution pattern with both human transferrin and chicken ovotransferrin.     

Structural organization of a 17 KB segment of the alpha 2 collagen gene: evaluation by R loop mapping.

A recombinant phage, SpC3, containing a 17 kb genomic DNA insert representing approximately 60% of the 3' portion of the sheep collagen alpha 2 gene, was evaluated by electron microscopic R loop analysis. A minimum of 17 intervening sequences (introns) and 18 alpha 2 coding sequences (exons) were mapped. With the exception of the 850 base pair exon located at the extreme 3' end of the insert, all exons contained 250 base pairs or less. The total length of all the exons in SpC3 was 3,014 base pairs. The length distribution of the 17 introns ranged from 300 to 1600 base pairs; together, all of the introns comprised 14,070 base pairs of SpC3 DNA. Thus, the DNA region required for coding the interspersed 3 kb of alpha 2 collagen genetic information was 5.6 fold longer than the corresponding alpha 2 mRNA coding sequences.     

Molecular isolation and sequence determination of the cDNA for the mouse sperm-specific lactate dehydrogenase-X gene

Several cDNA clones for the mouse lactate dehydrogenase-X (LDH-X), a sperm-specific glycolytic enzyme, were isolated from mouse testicular cDNA libraries constructed in the bacteriophage vectors, lambda gt11 and gt10. The largest cDNA clone contains an insert of 1135 base pairs in length and an open reading frame that encodes a 332 amino acid polypeptide with a molecular weight of 35.89 kD. The deduced amino acid sequence of this protein is in close agreement with the published sequence of mouse LDH-X obtained by direct protein sequencing. Northern analysis of RNA isolated from different tissues detected a single size mRNA of 1.5 kilobases in mouse testis but not in brain or liver. The Ldh-x structural gene was estimated to be about 12 kb in size as demonstrated by Southern hybridization analysis of mouse genomic DNA using the full-length cDNA as a probe.     

Molecular cloning and chromosomal mapping of the human gene for the testis-specific catalytic subunit of calmodulin-dependent protein phosphatase (calcineurin A).

A cDNA for an alternatively spliced variant of the testis-specific catalytic subunit of calmodulin dependent protein phosphatase (CaM-PrP) was cloned from a human testis library. The nucleotide sequence of 2134 base pairs (bp) encodes a protein of 502 amino acids (Mr approximately 57,132) and pI 7.0. The cDNA sequence differs from the murine form of this gene by a 30 bp deletion in the coding region, the position of which matches those in the two other genes for the catalytic subunit. These data indicate that this alternative splicing event arose prior to the divergence of the three genes. The deduced sequence of the human protein is only 88% identical to the homologous murine form, in striking contrast to the other two CaM-PrP catalytic subunits which are highly conserved between mouse and human (approximately 99%); this indicates a more rapid rate of evolution for the testis-specific gene. Analysis of Southern blots containing DNA from human-hamster somatic cell hybrids show that the gene is on human chromosome 8.     

Cytochrome c: gene structure, homology and ancestral relationships.

In this paper, the author notes the recommended definition of the word "homology" (i.e., indicating an ancestral relationship) and the recommended stipulation that "evidence for homology should be explicitly laid out". The postulated homology for somatic and testes-specific isozymes of cytochrome c is then examined, using recent data obtained from the study of cytochrome c genes. Consideration is also given to some newer findings of molecular biology and possibilities are considered for various types of change in the genome of an organism. Possible roles of introns, pseudogenes and multigene families are considered. The relationship of testes-specific cytochrome c to somatic cytochrome c is carefully considered from data obtained in experimental studies of genes of these two isozymes. If one assumes that these isozymes arose as a consequence of a gene duplication, data from rat and mouse genes indicate that the testes-specific isozyme has incorporated more amino acid changes than the somatic isozyme since the time of their divergence. However, when the 15 amino acid differences (testes-specific vs. somatic isozyme) are considered, there is virtually no similarity in these 15 positions of the testes-specific isozyme with any of the hypothetical ancestral sequences of the somatic isozyme. Nucleotide differences in cytochrome c genes have been evaluated by comparing genes for the two rodent cytochrome c isozymes to cytochrome c genes of fruit flies, chickens and humans. Comparisons of nucleotide substitution rates in genes for the two cytochrome c isozymes in rodents confirm the conclusions from amino acid sequence comparisons; namely, that more rapid nucleotide changes have occurred in the testes-specific cytochrome c gene, than in the somatic cytochrome c gene. Possible explanations for these findings are considered.     

Characterization of a mouse somatic cytochrome c gene and three cytochrome c pseudogenes.

Mouse contains two functional, but differentially expressed, cytochrome c genes. One of these genes is expressed in all somatic tissues so far examined. The other gene is expressed only in testis and is assumed to be spermatogenesis-specific. The nucleotide sequence of four mouse cytochrome c-like genes has been determined. One of these genes (MC1) contains an intron and encodes a polypeptide sequence identical to the published mouse somatic cytochrome c amino acid sequence. The other three genes can not properly encode a mouse cytochrome c protein and appear to be pseudogenes which have arisen via an insertion into the mouse genome of a cDNA copy of a cytochrome c mRNA molecule.     

Organization and chromosomal mapping of mouse Gh/tissue transglutaminase gene (Tgm2).

The mouse Gh/tissue transglutaminase gene (Tgm2), coding a dual-function protein that both binds guanosine triphosphate (GTP) and catalyzes the posttranslational modification of proteins by transamidation of glutamine residues, has been cloned. Sequence analysis of Tgm2 and comparison with the TGase sequences of other species allowed correction of several apparent sequencing artifacts in the Tgm2 cDNA. Tgm2 spans approximately 34 kb and has 13 exons and 12 introns. Although the structure of Tgm2 shows similarity to that of other transglutaminase genes, with introns ranging from 921 bp to >5 kb, several introns differ considerably in size from those of the human Gh gene, TGM2. Tgm2 maps to the distal region of mouse chromosome 2, a region syntenic to human chromosome 20q containing TGM2. Tgm2 is in the vicinity of two uncloned mouse mutations, diminutive (dm) and blind-sterile (bs). Genomic DNA from dm mice was unavailable; however, Southern blot analysis of bs DNA showed no gross rearrangements of Tgm2.     

Structure of the human cytochrome c oxidase subunit Vb gene and chromosomal mapping of the coding gene and of seven pseudogenes.

Subunit Vb of mammalian cytochrome c oxidase (COX; EC 1.9.3.1) is encoded by a nuclear gene and assembled with the other 12 COX subunits encoded in both mitochondrial and nuclear DNA. We have cloned the gene for human COX subunit Vb (COX5B) and determined the exon-intron structure by both hybridization analysis and DNA sequencing. The gene contains five exons and four introns; the four coding exons span a region of approximately 2.4 kb. The 5' end of the COX5B gene is GC-rich and contains many HpaII sites. Genomic Southern blot analysis of human DNA probed with the human COX Vb cDNA identified eight restriction fragments containing COX Vb-related sequences that were mapped to different chromosomes with panels of human x Chinese hamster somatic cell hybrids. Because only one of these fragments hybridized with a 210-bp probe from intron 4, we conclude that there is a single expressed gene for COX subunit Vb in the human genome. We have mapped this gene to chromosome 2, region cen-q13.     

Gene structure of a major form of phenobarbital-inducible cytochrome P-450 in rat liver

The gene structure of cytochrome P-450b, a major form of phenobarbital-inducible cytochrome P-450 in rat livers was elucidated by sequence analysis of the cloned genomic DNAs and was compared with the previously determined gene structures of cytochrome P-450e, a minor form of phenobarbital-inducible cytochrome P-450 and two forms of 3-methylcholanthrene-inducible cytochrome P-450 (P-450c and -d). The gene for cytochrome P-450b is 23 kilobase pairs (kb) long and is separated into 9 exons by 8 intervening sequences. This gene structure is very similar to that of cytochrome P-450e except for the first intron, the first intron being much longer in cytochrome P-450b gene (approximately 12 kb) than in cytochrome P-450e gene (3.2 kb), but differs greatly from the gene structures of two 3-methylcholanthrene-inducible cytochrome P-450s as pointed out previously (Sogawa, K., Gotoh, O., Kawajiri, K. & Fujii-Kuriyama, Y. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 5066-5070). The nucleotide sequences in all 9 exons and their flanking regions in introns show very close homology between the two phenobarbital-inducible cytochrome P-450 genes. Forty base substitutions are found in approximately 1900 nucleotides of all exonic sequences, and 15 of them result in 14 amino acid replacements. These base substitutions occur in relatively limited regions of the gene sequences. Most of them are found in exons 6, 7, 8, and 9, most frequently in exon 7 as described previously (Mizukami, Y., Sogawa, K., Suwa, Y., Muramatsu, M. & Fujii-Kuriyama, Y. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 3958-3962). The close sequence homology between the two phenobarbital-inducible cytochrome P-450 genes is also found to extend to the promoter region with one notable exception. The simple repeated sequences of (CA)n which is present at -254 position in cytochrome P-450e gene is also observed at the equivalent position in cytochrome P-450b gene, but the repetitiveness is greatly reduced in cytochrome P-450b gene ((CA)5 for P-450b versus (CA)19 for P-450e), and this may somehow be related to the difference in the level of cytochrome P-450b and P-450e in the inductive phase of phenobarbital administration.     

Sequence conservation and structural organization of the glycerol-3-phosphate dehydrogenase promoter in mice and humans.

Cloned segments of the mouse glycerol-3-phosphate dehydrogenase (GPDH) gene, Gdc-1, were used to screen a human library. Human clones obtained spanned 25 kilobases of genomic DNA containing the human GPDH gene, GPD1. The 4 kb of sequence obtained from the 5'-flanking region and first exon of GPD1 was compared with the corresponding mouse sequence. Both sequences share a HindIII site located in what has proven to be the highly conserved 3' untranslated region of an upstream gene of unknown function, D15Kzl. The 3.6-kilobase segment of mouse DNA located between D15Kzl and Gdc-1 was provisionally termed the GPDH promoter. Alignment of the mouse promoter with the corresponding human sequence revealed two conserved domains. An upstream distal promoter region is approximately 900 base pairs in length. A downstream or proximal promoter region consists of approximately 300 base pairs immediately upstream of a TATA-like box and contains the fat-specific elements 1 and 2. Analysis of the chromatin structure of the Gdc-1 promoter revealed four DNase I-hypersensitive sites. They were present in DNA of liver and brown fat, in which GPDH expression is high, but were absent in DNA of spleen, in which GPDH expression is low. Methylation studies of the promoter showed it to be heavily methylated in sperm. However, the DNA from each adult somatic tissue had a unique distribution of nonmethylated sites and could easily be identified by its methylation pattern. These data suggest a structural model of the promoter that explains how Gdc-1 expression is differentially regulated in many types of cells.     

Hormone sensitive lipase mRNA in both monocyte and macrophage forms of the human THP-1 cell line

The identity of the neutral cholesteryl ester hydrolase (CEH) in human monocyte/macrophages is uncertain. Prior studies indicate that hormone sensitive lipase (HSL) is a major CEH in mouse macrophages, and that HSL mRNA is present in human THP-1 monocytes. In the present study, HSL mRNA expression was examined in THP-1 cells as a function of differentiation status and cholesterol enrichment. By RT-PCR with primer pairs that span exon boundaries, HSL mRNA was demonstrated in THP-1 monocytes and phorbol-ester differentiated THP-1 macrophages. cDNA identities were confirmed by sequencing. By Northern blotting, with HSL cDNA as probe, THP-1 monocytes were found to contain HSL mRNA of approximately 3 and 3.9 kb. In THP-1 macrophages, the 3 kb mRNA was greatly diminished, while the level of the 3.9 kb mRNA was maintained. mRNA of approximately 3 and 3.9 kb are those expected of the 86-kDa (adipocyte) and 117-kDa (testicular) HSL isoforms, respectively. The presence of the testicular isoform mRNA was confirmed in THP-1 cells by amplification and sequencing of an isoform-specific cDNA. Additionally, Northern-blot comparisons showed that the 3 and 3.9 kb mRNA in THP-1 comigrated with the HSL mRNA in 3T3-L1 adipocytes and rat testis, respectively. The level of the 3.9 kb mRNA did not vary greatly with cholesterol enrichment. Thus, the HSL gene is transcribed in THP-1 cells both before and after differentiation into macrophages; after differentiation, the predominant mRNA is that for the 117-kDa isoform. This isoform is a CEH, and may mediate some CE turnover in THP-1 cells.