Comparative study of the histochemical properties, collagen content and architecture of the skeletal muscles of wild boar crossbred pigs and commercial hybrid pigs.

The histochemical properties, collagen content and architecture of Musculus longissimusthoracis (LT), Musculus pectoralis profundus (PP) and Musculus biceps femoris (BF) were compared in F(1) (half blood) and F(2) (quarter blood) wild boar crossbred pigs and commercial hybrid pigs, and Japanese wild pigs. F(1) pigs showed the lowest growth rate, followed by F(2) pigs. The most rapid growth was shown by the commercial pigs. The percentage weights of LT and PP muscle to body weight were larger in the wild boar crossbred pigs than commercial pigs. The muscles of the crossbred pigs contained type I and IIA myofibers at higher frequency and type IIB at lower frequency than the commercial pigs, except for LT muscle of F(2) pigs. The myofiber diameter in each type of muscle did not differ between pigs except for the smaller type IIA in BF muscle in commercial pigs. The total amount of intramuscular collagen was less in LT muscles than the others. More intramuscular collagen was found in the wild boar crossbred pigs than the commercial pigs in LT and PP muscles. With an increase of collagen content, the perimysial collagen architecture developed but not the endomysial architecture. Traits characteristic of the crossbred pigs seem to be inherited from the wild boar. Our results clarify that cross breeding with wild boar results in pigs with distinctive muscle characteristics in terms of histochemical properties, collagen content and architecture.

Regional rearrangements in chromosome 15q21 cause formation of cryptic promoters for the CYP19 (aromatase) gene.

Production of appropriate quantities of estrogen in various tissues is essential for human physiology. A single gene (CYP19), regulated via tissue-specific promoters, encodes the enzyme aromatase, which catalyzes the key step in estrogen biosynthesis. Aromatase excess syndrome is inherited as autosomal dominant and characterized by high systemic estrogen levels, short stature, prepubertal gynecomastia and testicular failure in males, and premature breast development and uterine pathology in females. The underlying genetic mechanism is poorly understood. Here, we characterize five distinct heterozygous rearrangements responsible for aromatase excess syndrome in three unrelated families and two individuals (nine patients). The constitutively active promoter of one of five ubiquitously expressed genes located within the 11.2 Mb region telomeric to the CYP19 gene in chromosome 15q21 cryptically upregulated aromatase expression in several tissues. Four distinct inversions reversed the transcriptional direction of the promoter of a gene (CGNL1, TMOD3, MAPK6 or TLN2), placing it upstream of the CYP19 coding region in the opposite strand, whereas a deletion moved the promoter of a fifth gene (DMXL2), normally transcribed from the same strand, closer to CYP19. The proximal breakpoints of inversions were located 17-185 kb upstream of the CYP19 coding region. Sequences at the breakpoints suggested that the inversions were caused by intrachromosomal nonhomologous recombination. Splicing the untranslated exon downstream of each promoter onto the identical junction upstream of the translation initiation site created CYP19 mRNA encoding functional aromatase protein. Taken together, small rearrangements may create cryptic promoters that direct inappropriate transcription of CYP19 or other critical genes.

Organization of the human aromatase p450 (CYP19) gene.

The human CYP19 (p450arom) gene is located in the 21.2 region on the long arm of chromosome 15 (15q21.2). This gene spans a region that consists of a 30 kb coding region and a 93 kb regulatory region ( approximately 123 kb total length). Its regulatory region contains at least 10 distinct promoters regulated in a tissue- or signaling pathway-specific manner. The Human Genome Project data published in 2000 enabled us to accurately align these promoters within the 93 kb regulatory region of the p450arom gene. Each promoter is regulated by a distinct set of regulatory sequences in DNA and transcription factors that bind to these specific sequences. In most vertebrates, p450arom expression is under the control of gonad- and brain-specific promoters. In humans, however, there are at least eight additional promoters that were apparently recruited throughout evolution, possibly via alterations in DNA. A critical mechanism that permits the use of such a large number of promoters seems to be the extremely promiscuous nature of the common splice acceptor site because, with activation of each promoter, an untranslated first exon is spliced onto this common junction immediately upstream of the translation start site in the coding region. These partially tissue-specific promoters are used in the gonads, bone, brain, vascular tissue, adipose tissue, skin, fetal liver, and placenta for estrogen biosynthesis necessary for human physiology. Ovary and testis use promoter II, which is located immediately upstream of the coding region. The adipose tissue in general, including adipose tissue of the disease-free breast, on the other hand, maintains low levels of aromatase expression primarily via promoter I.4, which lies 73 kb upstream of the common coding region. Promoters I.3 and II are used only minimally in normal breast adipose tissue. Promoter II and I.3 activities in breast cancer tissue, however, are strikingly increased. Additionally, the endothelial-type promoter I.7 is also upregulated in breast cancer. Therefore, breast tumor tissue takes advantage of four promoters (II, I.3, I.7, and I.4) for aromatase expression and estrogen production. The sum of p450arom mRNA species arising from these four promoters contributes significantly to elevated levels of total p450arom mRNA in breast cancer in contrast to the normal breast that uses promoter I.4. Because each mRNA species contains the identical coding region regardless of the variable untranslated first exon, the encoded protein functions as the aromatase enzyme in each case.

The human CYP19 (aromatase P450) gene: update on physiologic roles and genomic organization of promoters.

The human CYP19 (P450arom) gene is located in the chromosome 15q21.2 region and is comprised of a 30 kb coding region and a 93 kb regulatory region. The Internet-based Human Genome Project data enabled us to elucidate its complex organization. The unusually large regulatory region contains 10 tissue-specific promoters that are alternatively used in various cell types. Each promoter is regulated by a distinct set of regulatory sequences in DNA and transcription factors that bind to these specific sequences. In most mammals, P450arom expression is under the control of gonad- and brain-specific promoters. In the human, however, there are at least eight additional promoters that seemed to have been recruited throughout the evolution possibly via alterations in DNA. One of the key mechanisms that permit the recruitment of such a large number of promoters seems to be the extremely promiscuous nature of the common splice acceptor site, since activation of each promoter gives rise splicing of an untranslated first exon onto this common junction immediately upstream of the translation start site in the coding region. These partially tissue-specific promoters are used in the gonads, bone, brain, vascular tissue, adipose tissue, skin, fetal liver and placenta for physiologic estrogen biosynthesis. The most recently characterized promoter (I.7) was cloned by analyzing P450arom mRNA in breast cancer tissue. This TATA-less promoter accounts for the transcription of 29-54% of P450arom mRNAs in breast cancer tissues and contains endothelial-type cis-acting elements that interact with endothelial-type transcription factors, e.g. GATA-2. We hypothesize that this promoter may upregulate aromatase expression in vascular endothelial cells. The in vivo cellular distribution and physiologic roles of promoter I.7 in healthy tissues, however, are not known. The gonads use the proximally located promoter II. The normal breast adipose tissue, on the other hand, maintains low levels of aromatase expression primarily via promoter I.4 that lies 73 kb upstream of the common coding region. Promoters I.3 and II are used only minimally in normal breast adipose tissue. Promoters II and I.3 activities in the breast cancer, however, are strikingly increased. Additionally, the endothelial-type promoter I.7 is also upregulated in breast cancer. Thus, it appears that the prototype estrogen-dependent malignancy breast cancer takes advantage of four promoters (II, I.3, I.7 and I.4) for aromatase expression. The sum of P450arom mRNA species arising from these four promoters markedly increase total P450arom mRNA levels in breast cancer compared with the normal breast.

Estrogen excess associated with novel gain-of-function mutations affecting the aromatase gene.

BACKGROUND: Gynecomastia of prepubertal onset may result from increased estrogen owing to excessive aromatase activity in extraglandular tissues. A gene in chromosome 15q21.2 encodes aromatase, the key enzyme for estrogen biosynthesis. Several physiologic tissue-specific promoters regulate the expression of aromatase, giving rise to messenger RNA (mRNA) species with an identical coding region but tissue-specific 5'-untranslated regions in placenta, gonads, brain, fat, and skin. METHODS: We studied skin, fat, and blood samples from a 36-year-old man, his 7-year-old son, and an unrelated 17-year-old boy with severe gynecomastia of prepubertal onset and hypogonadotropic hypogonadism caused by elevated estrogen levels. RESULTS: Aromatase activity and mRNA levels in fat and skin and whole-body aromatization of androstenedione were severely elevated. Treatment with an aromatase inhibitor decreased serum estrogen levels and normalized gonadotropin and testosterone levels. The 5'-untranslated regions of aromatase mRNA contained the same sequence (FLJ) in the father and son and another sequence (TMOD3) in the unrelated boy; neither sequence was found in control subjects. These 5'-untranslated regions normally make up the first exons of two ubiquitously expressed genes clustered in chromosome 15q21.2-3 in the following order (from telomere to centromere): FLJ, TMOD3, and aromatase. The aromatase gene is normally transcribed in the direction opposite to that of TMOD3 and FLJ. Two distinct heterozygous inversions reversed the direction of the TMOD3 or FLJ promoter in the patients. CONCLUSIONS: Heterozygous inversions in chromosome 15q21.2-3, which caused the coding region of the aromatase gene to lie adjacent to constitutively active cryptic promoters that normally transcribe other genes, resulted in severe estrogen excess owing to the overexpression of aromatase in many tissues.

Cloning and characterization of a novel endothelial promoter of the human CYP19 (aromatase P450) gene that is up-regulated in breast cancer tissue.

Intratumoral expression of aromatase P450 (P450arom) promotes the growth of breast tumors via increased local estrogen concentration. We cloned a novel 101-bp untranslated first exon (I.7) that comprises the 5'-end of 29-54% of P450arom transcripts isolated from breast cancer tissues (n = 7). The levels of P450arom transcripts with exon I.7 were significantly increased in breast tumor tissues and adipose tissue adjacent to tumors. We identified a promoter immediately upstream of exon I.7 and mapped this to about 36 kb upstream of ATG translation start site of the CYP19 (aromatase cytochrome P450) gene. Sequence analysis of I.7 revealed a TATA-less promoter containing an initiator, two consensus GATA sites, and cis-regulatory elements found in megakaryocytes and endothelial type promoters. Luciferase activity directed by the promoter I.7 sequence (-299/+81 bp) was 4-fold greater than a minimum length promoter sequence (-35/+81 bp) in human microvascular endothelial cells (HMEC-1), but only 2-fold greater in MCF-7 breast malignant epithelial cells. There was no promoter activity in primary breast adipose fibroblasts. Site-directed mutations demonstrated that maximal basal promoter activity required two GATA motifs at -146/-141 bp and -196/-191 bp. Gel shift and deoxyribonuclease I footprinting assays demonstrated the binding of GATA-2 transcription factor but not GATA-1 to the -196/-191-bp region. Overexpression of GATA-2 in HMEC-1 cells increases promoter I.7 activity by 5-fold. In conclusion, promoter I.7 is a GATA-2-regulated endothelial promoter of the human CYP19 gene and may increase estrogen biosynthesis in vascular endothelial cells of breast cancer. The activity of this promoter may also be important for intracrine and paracrine effects of estrogen on blood vessels.