David R. Joseph

Structure, Function, and Regulation of Androgen-Binding Protein/Sex Hormone-Binding Globulin

Despite over 20 years of research, the functions of ABP and SHBG remain elusive. The major reason for this lack of knowledge has been the unavailability of natural mutants with clinical defects for study. There is strong evidence that these binding proteins do act to modulate the gene regulatory actions of nuclear sex steroid receptors by controlling the availability of androgens and estrogens. In plasma, SHBG controls the metabolic clearance rate of sex steroids. In addition there is strong evidence that they have a much broader function. The identification of plasma membrane receptors in target tissues and the finding of homologous domains in several developmental proteins support other functions. Moreover, other experiments suggest the proteins may actually be hormones or growth factors. These findings are not compatible with a model that has the proteins only regulating free steroid hormone levels. Obviously, much more experimentation will be necessary to reveal the functions of ABP and SHBG. The recent discoveries have offered several clues to their functions and open new routes for study. These experiments, coupled with newly developed techniques, such as gene knockout by homologous recombination, make one optimistic that the functions of these unique proteins will be deciphered in the near future.

Molecular basis of androgen insensitivity

Male sexual differentiation and development proceed under direct control of androgens. Androgen action is mediated by the intracellular androgen receptor, which belongs to the superfamily of ligand-dependent transcription factors. In the X-linked androgen insensitivity syndrome, defects in the androgen receptor gene have prevented the normal development of both internal and external male structures in 46,XY individuals. The complete form of androgen insensitivity syndrome is characterized by 46,XY karyotype, external female phenotype, intra-abdominal testes, absence of uterus and ovaries, blindly ending vagina, and gynecomastia. There is also a group of disorders of androgen action that result from partial impairment of androgen receptor function. Clinical indications can be abnormal sexual development of individuals with a predominant male phenotype with severe hypospadias and micropenis or of individuals with a predominantly female phenotype with cliteromegaly, ambiguous genitalia, and gynecomastia. Complete or gross deletions of the androgen receptor gene have not been frequently found in persons with the complete androgen insensitivity syndrome, whereas point mutations at several different sites in exons 2--8 encoding the DNA- and androgen-binding domain have been reported in both partial and complete forms of androgen insensitivity, with a relatively high number of mutations in two clusters in exons 5 and 7. The number of mutations in exon 1 is extremely low, and no mutations have been reported in the hinge region, located between the DNA-binding domain and the ligand-binding domain. The X-linked condition of spinal and bulbar muscle atrophy (Kennedys disease) is characterized by a progressive motor neuron degeneration associated with signs of androgen insensitivity and infertility. The molecular cause of spinal and bulbar muscle atrophy is an expanded length (>40 residues) of one of the polyglutamine stretches in the N-terminal domain of the androgen receptor. (Steroids 61:172-175, 1996)

Localization of histidine decarboxylase mRNA in rat brain

The recent cloning of a cDNA encoding fetal rat liver histidine decarboxylase (HDC), the synthesizing enzyme for histamine, allows the study of the central histaminergic system at the molecular level. To this end, Northern blot and in situ hybridization analyses were used to determine the regional and cellular distribution of neurons which express HDC mRNA in rat brain. Three hybridizing species which migrate as 1.6-, 2.6-, and 3.5-kb RNA were identified with Northern blots. The major (2.6 kb) and minor (3.5 kb) species, characteristic of HDC mRNA in fetal liver, were expressed at high levels in diencephalon and at just detectable levels in hippocampus, but not in other brain regions. In contrast, the 1.6-kb species was present in all brain regions examined except the olfactory bulb. Cells which contain HDC mRNA were found by in situ hybridization in the hypothalamus; HDC mRNA-containing cells were not detected in other areas, including the hippocampus. Hypothalamic neurons which express HDC mRNA were localized to all aspects of the tuberomammillary nucleus, a result consistent with previous immunohistochemical findings.

Distribution of immunoreactive androgen-binding protein/sex hormone-binding globulin in tissues of the fetal rat

Androgen-binding protein/sex hormone-binding globulin (ABP/SHBG) is an extracellular carrier protein that binds androgens and estrogens with high affinity. In the adult, ABP/SHBG is thought to function in the male reproductive system and the general circulation in both sexes to modulate the actions of sex steroids. The ABP/SHBG gene is also expressed in the embryonic rat liver, where SHBG is secreted into the fetal blood of male and female rats. The embryo also expresses an alternative SHBG with a unique N-terminal sequence. In this study, the distribution of immunoreactive SHBG in the 17-day-old male fetal rat was determined with six antisera. In general, all of the antisera reacted with the same structures. Specific tissue immunoreactivity was mostly cytoplasmic and/or extracellular. By far the most prominent immunoreactive structures were the mesoderm-derived tissues: connective tissue, striated and cardiac muscle, cartilage, and the liver hematopoietic system. In addition, all regions of the fetal brain contained immunoreactive neurons. In the developing male reproductive system, there was minor reactivity in the testicular cords, whereas the connective tissue in the differentiating Wolffian duct stained with all of the antisera. The Wolffian duct epithelium and epithelia in other developing organs contained small amounts of immunoreactive SHBG, except for the lung, which stained in the epithelial extracellular matrix. An antibody raised against a unique N-terminal peptide specific for the alternative SHBG protein revealed that it was also present in many tissues. These data suggest that SHBG is important for the differentiation of mesodermal tissues. SHBG may modulate the action of androgens in embryonic stroma, thereby regulating development of the epithelium in hormone-dependent tissues.

The androgen-binding protein gene is expressed in CD1 mouse testis

Androgen-binding protein (ABP) is a testicular Sertoli cell secretory protein that acts as a carrier of androgen in the male reproductive tract. ABP has been characterized from a wide range of animal species, including man, rabbit and rat. However, it has been widely accepted that mice do not produce testicular ABP. We have used immunological and molecular biological techniques to demonstrate that the ABP gene is expressed in the CD1 mouse. Steroid-binding, radioimmunoassay and immunocytochemical studies demonstrated that ABP is present in mouse testis and epididymis, but at 1/50 to 1/25 the level of rat epididymis. A 1.7 kilobase mRNA, homologous with rat ABP cDNA, was identified in mouse testis and Sertoli cells by Northern blot hybridization, but at a much lower level than in the rat. An ABP cDNA was isolated from a mouse testis cDNA library and encoded a protein (403 residues) with 89% of the amino acid residues identical to rat ABP, including a signal peptide. Our results indicate that ABP is expressed in the mouse and past failures to detect androgen-binding activity were due to the low level of ABP protein.

Structural Analysis of the Human and Rat Androgen Receptors and Expression in Male Reproductive Tract Tissues

The androgen receptor (AR) is a key regulatory protein required for normal male sexual differentiation and development. Spermatogenesis, sperm maturation and accessory sex gland function depend on the action of androgen mediated through its receptor. Our understanding of AR has been limited by its low concentration in tissues and instability during isolation. The recent cloning of A R cDNAs by our group’-’ and by othersC6 has made possible a detailed analysis of its primary structure. From genetic studies of the androgen insensitivity syndrome or testicular feminization, it was established that the X chromosome is the probable locus of the A R gene. An oligonucleotide probe with sequence homology to the DNA-binding domains of other steroid hormone receptors was used to isolate a partial genomic clone from an X chromosome library.’ Proof for the identity of the clone came from transfection of COS cells and expression of a high-affinity, specific androgen-binding protein. Sequence data from this partial clone led to the isolation of complementary DNA clones containing the complete DNA coding sequence for human and rat AR” and the development of antisera that react selectively with the native A R both by sucrose gradient analysis and immunocytochemical staining?

Sequence and functional relationships between androgen-binding protein/sex hormone-binding globulin and its homologs protein S, Gas6, laminin, and agrin

Androgen-binding protein/sex hormone-binding globulin (ABP/SHBG) is an extracellular binding protein that regulates the bioavailability of sex steroids. ABP/SHBG is closely related to the globular (G) domain of vitamin K-dependent protein S family of proteins and more distantly related to the G domains of several extracellular matrix proteins. ABP/SHBG appears to have evolved from the fusion of two ancestral G domains. Expanding evidence suggests that ABP/SHBG has other functions that are mediated through membrane binding, including signal transduction; however, the types of binding proteins (receptors) have not been identified. Sequence comparisons of ABP/SHBG with G domains of its homologs protein S, Gas6, laminin, and agrin have identified regions of ABP/SHBG that may bind receptors related to homolog receptors. These membrane receptors include beta-integrins, alpha-dystroglycan, and receptor tyrosine kinases. The G domains of laminin and related proteins have clearly evolved from a common ancestor to interact with specific receptors and binding proteins. It remains to be determined if ABP/SHBG followed this evolutionary pathway.

Complex structure and regulation of the ABP/SHBG gene

Extracellular androgen-binding proteins (ABPs) are thought to modulate the regulatory functions of androgens and the trans-acting nuclear androgen receptor. Testicular ABP and plasma sex hormone-binding globulin (SHBG), which is produced in the liver, are encoded by the same gene. We report here that the ABP/SHBG gene is also expressed in fetal rat liver and adult brain. Immunoreactive ABP was localized in the brain and fetal liver and mRNAs were identified in both tissues by northern blot hybridization. Analysis of brain and fetal liver cDNA clones revealed alternatively processed RNAs with sequence characteristics suggesting the encoded proteins could act as competitors of ABP/SHBG binding to cell surface receptors. One cDNA represented a fused transcript of the ABP/SHBG gene and the histidine decarboxylase gene that was apparently formed by a trans-splicing process. Gene sequencing experiments indicate that tissue-specific ABP/SHBG gene promoter-enhancer elements are utilized in testis, brain and fetal liver. These data demonstrate that the structure, RNA transcript processing and likely regulation of the ABP/SHBG gene are very complex.

Cloning of the cDNA encoding human histidine decarboxylase from an erythroleukemia cell line and mapping of the gene locus to chromosome 15

The biogenic amine histamine is an important modulator of numerous physiological processes, including neurotransmittance, gastric acid secretion and smooth muscle tone. The biosynthesis of histamine is catalyzed by the enzyme, L-histidine decarboxylase (HDC). We have previously reported the cloning and sequence of the cDNA encoding rat HDC. Utilizing the rat HDC cDNA as probe the full-length cDNA encoding human HDC was identified and characterized. The encoded protein of 662 amino acid residues has a molecular weight of 74,148. Homology comparisons of the deduced amino acid sequence with rat HDC and dopa decarboxylases from three species have revealed highly related regions. These comparisons have identified domains of amino acid decarboxylases that are highly conserved and are likely important for enzyme-substrate interaction. A dissimilar region in human and rat HDC primary translated protein near the C-terminus would appear not to be important for catalysis and may be removed by proteolysis. This processing phenomenon could be in part responsible for regulation of HDC activity. The human HDC cDNA was also utilized to map the chromosomal location of the human HDC gene locus (HDC). Analysis of human-rodent cell hybrids revealed that the HDC gene segregates with Chromosome 15. No restriction length polymorphisms in the human population were detected after cleavage of the DNAs with 12 restriction endonucleases.

Purification of sea urchin ribosomal RNA genes with a single-strand specific nuclease

Ribosomal RNA genes (rDNA) from Lytechinus variegatus were isolated by selective heat denaturation of main band DNA followed by single-strand specific nuclease (S1) treatment to remove the single-stranded DNA. After S1 nuclease treatment the partially purified fraction contained 10% rDNA, representing a 50-fold purification. Preparative CsCl centrifugation of this fraction resulted in highly purified rDNA with an average molecular weight of 1.9 - 10(7) and no single-strand breaks. High molecular weight sea urchin DNA was refractory to selective heat denaturation. DNA with an average molecular weight of greater than or equal to 2.9 - 10(7) was only 60-80% denatured after heating 13 degrees C above the Tm, whereas, DNA with an average molecular weight of less than or equal to 1.9 - 10(7) was 98% denatured. This phenomenon appears not to be due to time, buffer, or pH, but is dependent on size.