Lactobacillus fermentum L930BB and Bifidobacterium animalis subsp. animalis IM386 initiate signalling pathways involved in intestinal epithelial barrier protection.

The manipulation of intestinal microbiota with beneficial microbes represents a promising alternative or adjunct therapy in gastrointestinal disorders and inflammation. The current study aims to clarify the signalling pathways and evaluate the possible beneficial effects of the combination of two strains. We used a dextran sulphate sodium (DSS)-induced mouse model of colitis. RNA extracted from the middle part of the colon tissue was used for examination of the global gene expression with Affymetrix microarrays. An enrichment analysis of the KEGG pathways was performed, and a subset of genes associated with intestinal epithelial barrier function was verified with qPCR. A clinical condition assessment of the differently treated mice revealed that the combination of these two bacterial strains was safe for use as a dietary supplement. All animals treated with DSS had affected colons and suffered weight loss. There were very small differences between the diseased groups, although the depth of inflammation was lower when cyclosporine A or the strain mixture was used. We discovered that the prophylactic administration of the Lactobacillus fermentum L930BB (L930BB) and Bifidobacterium animalis subsp. animalis IM386 (IM386) strains led to an anti-apoptotic pathway through phosphatidylinositol-4,5-bisphosphate 3-kinase (PI3K)/Akt and to the activation of pathways involved in the regulation of actin cytoskeleton via protein kinase C and GTPases. Reorganisation of actin cytoskeleton and decreased apoptosis are both helpful in intestinal epithelial cell reconstitution. We confirm important previous observations, showing that these pathways are downstream targets of Toll-like receptor 2 and fibroblast growth factor initiated signalling. Taken together, these results suggest that the combination of L930BB and IM386 could aid in the regeneration of the intestinal epithelium during pathogenesis via pattern recognition receptors and the stimulation of growth factor synthesis.

Initiation of steroidogenesis precedes expression of cholesterologenic enzymes in the fetal mouse testes.

Sexual differentiation is a carefully regulated process that ultimately results in a development of the male or female phenotype. Proper development of the male phenotype is dependent upon the action of testosterone and anti-mullerian hormone. Leydig cells start to produce testosterone around day 12.5 in the fetal mouse testis, and continue to produce high levels of this hormone throughout gestation. In the present study, we examined whether expression of lanosterol 14alpha-demethylase (cyp51) and cytochrome P450 NADPH reductase, both involved in the cholesterol production, occurs simultaneously with proteins required for the production of steroid hormones. Immunocytochemical staining with the antibodies against cyp51, cytochrome P450 NADPH reductase, steroidogenic acute regulatory protein (StAR) and 3beta-hydroxysteroid dehydrogenase I (3beta-HSD I) was used to determine the ontogeny of expression of these four proteins. As expected, 3beta-HSD I and StAR proteins were detected on day 12.5 p.c., while expression of cyp51 and NADPH cytochrome P450 reductase appeared 1 day later, on day 13.5. Thereafter, the expression of all four proteins remained strong throughout gestation. Results of this study suggest that initial steps of steroid hormone production in murine Leydig cells are mostly dependent on exogenously derived cholesterol, while from day 13.5 onwards, mouse Leydig cells are able to synthesize cholesterol and are therefore not dependent on exogenous cholesterol resources.

Follicular sterol composition in gonadotrophin stimulated women with polycystic ovarian syndrome.

This is the first study evaluating whether oocyte development and fertilization competence are related to intrafollicular concentration of cholesterol, meiosis-activating sterols and progesterone, after human chorionic gonadotrophin (HCG) administration of women with polycystic ovarian syndrome (PCOS). The concentration of follicular fluid meiosis-activating sterol (FF-MAS) significantly increased in the periovulatory period from 10-14 to 34-38 h after HCG administration, while the concentration of testis meiosis-activating sterol (T-MAS) decreased, suggesting a HCG-dependent inhibition of sterol Delta14-reductase. There was no correlation between follicular lanosterol, FF-MAS, T-MAS, and progesterone concentrations and the presence or absence of MII oocytes. Interestingly, free cholesterol level was significantly lower and FF-MAS/cholesterol and progesterone/cholesterol ratios significantly higher in follicles containing MII oocytes compared to follicles from which oocytes were not retrieved. Yet, fertilization and embryo quality did not correlate with follicular sterols. This knowledge should be beneficial for the implementation of protocols for in vitro maturation process, usually used in PCOS patients.

Combinations of genetic changes in the human cAMP-responsive element modulator gene: a clue towards understanding some forms of male infertility?

The cAMP-responsive element modulator (CREM) gene plays a pivotal role in the mouse spermatogenesis, but its role in the human infertility has not been fully established. We performed a mutation screening in 13 Slovenian men with round spermatid arrest and in six controls. Eleven genetic changes have been identified in the human CREM gene, three novel single-nucleotide polymorphisms [within the promoters P1, P3 and intervening sequence 1 (IVS1)], one insertion (IVS2) and one non-sense mutation (exon gamma). Some infertile patients seem to accumulate potentially harmful genetic changes. We identified a patient with no CREM immunoreactive protein that was homozygous for the nucleotide changes in all promoters, IVS 1, 2, 6, and was heterozygous for the mutation in exon gamma. Interestingly, insertion in IVS2 (IVS2-58_55insT) results in a four-fold decrease in binding of nuclear proteins. Computer predictions suggested the presence of a potential novel CREM promoter, however, random amplification of cDNA ends from the human testis cDNA library was not successful in confirming a novel transcription start site of the CREM gene. Screening of a larger number of patients and controls is required to elucidate whether the observed combinations of genetic changes in the CREM gene can explain some forms of male infertility.

A functional cytochrome P450 lanosterol 14 alpha-demethylase CYP51 enzyme in the acrosome: transport through the Golgi and synthesis of meiosis-activating sterols.

Mammalian lanosterol 14 alpha-demethylase (CYP51) is a microsomal cytochrome P450 that demethylates lanosterol to FF-MAS, an oocyte meiosis-activating sterol and late intermediate of cholesterol biosynthesis. Herein we report CYP51 unequivocally localized to acrosomal membranes of male germ cells in mouse, bull, and ram, in which it synthesizes FF-MAS in the presence of the acrosomal form of nicotinamide adenine dinucleotide phosphate reduced-P450 reductase. In the mouse, CYP51 (53 kDa) resides in endoplasmic reticulum (ER) and Golgi during all phases of acrosome development, indicating an intracellular transport from ERs through the Golgi to the acrosome. CYP51 (50 kDa) also resides on acrosomal membranes of bull- and ram-ejaculated sperm. In mouse liver, a 53-kDa CYP51 is no longer detected in trans Golgi, suggesting retrieval back to the ER and no further transport to other organelles. Glycosylated high-molecular-mass CYP51-immunoreactive proteins in acrosomal membranes of bull and ram and Golgi-enriched fractions of mouse liver indicate that mammalian CYP51s are subjected to posttranslational modifications in the Golgi. In conclusion, CYP51 is the first cytochrome P450 enzyme to be detected on acrosomal membranes. It exhibits a unique, cell-type-specific intracellular transport that is in agreement with its cell-type-specific physiological role: production of cholesterol in the liver and sterols with signaling properties in sperm. Demethylation of lanosterol to FF-MAS by the acrosomal lanosterol 14 alpha-demethylase enzyme complex demonstrates for the first time the ability of ejaculate sperm to synthesize meiosis-activating sterols.

Lanosterol 14alpha-demethylase and MAS sterols in mammalian gametogenesis.

The lanosterol 14alpha-demethylase protein complex is composed of a cytochrome P450 enzyme CYP51 and its redox partner NADPH cytochrome P450 reductase. The complex participates in cholesterol biosynthesis and produces folicular fluid meiosis activating sterol (FF-MAS) from lanosterol. FF-MAS is metabolized further by sterol Delta14-reductase to testis-meiosis activating sterol (T-MAS). Additional enzymatic steps are needed before cholesterol is produced. Using the anti-human CYP51 antibody we have studied CYP51 protein expression by confocal microscopy in male and female mouse gonads. Leydig cells and acrosomes of spermatids express the highest levels of the CYP51 protein. CYP51 protein is also detected in primary mouse oocytes of non-treated mice and in some granulosa cells. While regulatory mechanisms responsible for FF-MAS accumulation in the ovary are not yet established, two mechanisms contributing to production the of T-MAS in the testis have been found. Potential in vivo roles of FF-MAS and T-MAS in fertilization are discussed.

New steroid 5alpha-reductase type I (SRD5A1) homologous sequences on human chromosomes 6 and 8.

To date, two genes encoding 5alpha-reductase isoenzymes are known (type I, type II), and one type I pseudogene. The divergent localization of these genes and the still not fully understood function of the encoded enzymes as well as the perplexing results we obtained after sequencing PCR-amplified SRD5A1 gene fragments (out of genomic DNA), made us assume that, in addition to the known SRD5A1 gene, one or more different human 5alpha-reductase type I coding genes may exist. Our research provide the first evidence for the existence of two new SRD5A1 related, previously unidentified sequences in the human genome. These sequences which were localized to chromosomes 6 and 8 are highly homologous (> 99%) to SRD5A1, and also do not contain any deletions or insertions that are otherwise a characteristic of the SRD5API pseudogene. Our results imply that these sequences may be either coding parts of yet unknown, active SRD5A1 genes, and/or of previously unidentified pseudogenes. These findings additionally support data of Chen et al. who confirmed the existence of various SRD5A1 proteins in cultured human skin cells.

Lanosterol 14alpha-demethylase (CYP51), NADPH-cytochrome P450 reductase and squalene synthase in spermatogenesis: late spermatids of the rat express proteins needed to synthesize follicular fluid meiosis activating sterol.

Lanosterol 14alpha-demethylase (CYP51) is a cytochrome P450 enzyme involved primarily in cholesterol biosynthesis. CYP51 in the presence of NADPH-cytochrome P450 reductase converts lanosterol to follicular fluid meiosis activating sterol (FF-MAS), an intermediate of cholesterol biosynthesis which accumulates in gonads and has an additional function as oocyte meiosis-activating substance. This work shows for the first time that cholesterogenic enzymes are highly expressed only in distinct stages of spermatogenesis. CYP51, NADPH-P450 reductase (the electron transferring enzyme needed for CYP51 activity) and squalene synthase (an enzyme preceding CYP51 in the pathway) proteins have been studied. CYP51 was detected in step 3-19 spermatids, with large amounts in the cytoplasm/residual bodies of step 19 spermatids, where P450 reductase was also observed. Squalene synthase was immunodetected in step 2-15 spermatids of the rat, indicating that squalene synthase and CYP51 proteins are not equally expressed in same stages of spermatogenesis. Discordant expression of cholesterogenic genes may be a more general mechanism leading to transient accumulation of pathway intermediates in spermatogenesis. This study provides the first evidence that step 19 spermatids and residual bodies of the rat testis have the capacity to produce MAS sterols in situ.

Characterization of the mouse lanosterol 14alpha-demethylase (CYP51), a new member of the evolutionarily most conserved cytochrome P450 family.

Genes encoding sterol 14alpha-demethylases in eukaryotes and in Mycobacterium belong to the CYP51 family which is evolutionary the most conserved gene family within the cytochrome P450 superfamily. We have characterized a new member of this family, the mouse lanosterol 14alpha-demethylase, with the aim to study the in vivo role of this gene in spermatogenesis in mammals. The amino acid sequence of mouse Cyp51 is 96% identical to rat and 91% to human. Comparison of all known CYP51 proteins by the neighbor-joining method suggests that fungal and animal CYP51 genes arose from a common ancestral gene (98.3% probability) and interestingly, that plant and bacterial CYP51 genes share a common progenitor (88.8% probability). This suggests that the first CYP51 gene may have arisen in eukaryotes and has been transferred horizontally from plants to Mycobacterium. The mouse CYP51 gene is approximately 17-kb long and contains 10 exons. Transcription starts at several locations within the CpG island, which is characteristic for the TATA-less housekeeping genes. The mouse 5'-untranslated region (800 bp) contains putative cAMP-responsive elements (CRE), sterol regulatory elements (SRE) and GC-boxes at positions similar to human and rat, suggesting an evolutionary conserved mechanism of CYP51 transcriptional regulation in mammals. The mouse Cyp51 gene resides on chromosome 5, region A2, close to the centromere. No signals outside this region were detected as well as no evidence of processed pseudogenes using long PCR was found. This indicates that the mouse genome most likely lacks CYP51 processed pseudogenes.

Molecular cloning and partial characterisation of the mouse Cyp51 cDNA.

Northern analysis of the mouse testis and liver RNA show two types of lanosterol 14alpha-demethylase (CYP51) transcripts, somatic and a testis-specific transcript. At least two CYP51 mRNAs are expressed in liver and testis, while the smallest transcript is expressed only in testis. The partial mouse Cyp51 cDNA (1052 bp) was obtained by RT-PCR cloning and was also found in expressed sequence tag (EST) clones. Bacterial artificial chromosome (BAC) clones containing mouse Cyp51 gene were also found. The coding part of the partial mouse CYP51 is 93.9% homologous to the rat and 87.9% to the human CYP51 cDNAs. There is less than 2% variation between the CYP51 EST clones to the RT-PCR cloned partial cDNA and BAC clones.

Lanosterol 14alpha-demethylase (CYP51)--a cholesterol biosynthetic enzyme involved in production of meiosis activating sterols in oocytes and testis--a minireview.

CYP51 is an evolutionarily conserved, housekeeping gene of the cytochrome P450 superfamily which is involved in cholesterol biosynthesis in animals. The two intermediates of cholesterol biosynthetis pathway, sterol FF-MAS, produced by CYP51 and the following sterol T-MAS, accumulate in follicular fluid and in testis. CYP51 is expressed in all tissues in mammals with the highest level in the testis. In rat, expression peaks in postmeiotic male germ cells of the testis. Promoters of the human and rat CYP51 genes contain SRE and CRE elements which indicate two main regulatory routes--the sterol-dependent regulation and the cAMP-dependent regulation. While feedback regulation by sterols is characteristic for all genes involved in cholesterol biosynthesis and homeostasis, the cAMP-dependent regulation is unique, indicating that CYP51 may play tissue-specific roles distinct from cholesterol biosynthesis.

Cyclic adenosine 3',5'-monophosphate(cAMP)/cAMP-responsive element modulator (CREM)-dependent regulation of cholesterogenic lanosterol 14alpha-demethylase (CYP51) in spermatids.

Lanosterol 14alpha-demethylase (CYP51) produces MAS sterols, intermediates in cholesterol biosynthesis that can reinitiate meiosis in mouse oocytes. As a cholesterogenic gene, CYP51 is regulated by a sterol/sterol-regulatory element binding protein (SREBP)-dependent pathway in liver and other somatic tissue. In testis, however, cAMP/cAMP-responsive element modulator CREMtau-dependent regulation of CYP51 predominates, leading to increased levels of shortened CYP51 mRNA transcripts. CREM-/- mice lack the abundant germ cell-specific CYP51 mRNAs in testis while expression of somatic CYP51 transcripts is unaffected. The mRNA levels of squalene synthase (an enzyme preceding CYP51 in cholesterol biosynthesis in testis of CREM-/- mice are unchanged as compared with wild-type animals, showing that regulation by CREMtau is not characteristic for all cholesterogenic genes expressed during spermatogenesis. The -334/+314 bp CYP51 region can mediate both the sterol/SREBP-dependent as well as the cAMP/CREMtau-dependent transcriptional activation. SREBP-1a from somatic cell nuclear extracts binds to a conserved CYP51-SRE1 element in the CYP51 proximal promoter. The cAMP-dependent transcriptional activator CREMtau from germ cell nuclear extracts binds to a conserved CYP51-CRE2 element while no SREBP-1 binding is observed in germ cells. The two regulatory pathways mediating expression of CYP51 describe this gene as a cholesterogenic gene (SREBP-dependent expression in liver and other somatic cells) and also as a haploid expressed gene (CREMtau-dependent expression in haploid male germ cells). While in somatic cells all genes involved in cholesterol biosynthesis are regulated coordinately by the sterol/SREBP-signaling pathway, male germ cells contain alternate routes to control expression of cholesterogenic genes.

Characteristics of the heterologously expressed human lanosterol 14alpha-demethylase (other names: P45014DM, CYP51, P45051) and inhibition of the purified human and Candida albicans CYP51 with azole antifungal agents.

Human and Candida albicans CYP51 were purified to homogeneity after GAL10-based heterologous expression in yeast in order to resolve the basis for the selective inhibition of the fungal enzyme over the human orthologue by the azole drugs ketoconazole and itraconazole, used in the treatment of systemic fungal infection. The purified proteins have similar spectral characteristics, both giving a maximum at 448 nm in reduced carbon monoxide difference spectra. Substrate affinity constants of 20.8 and 29.4 microM and Vmax of 0. 15 and 0.47 nmol/min/nmol were observed for C. albicans and human enzymes, respectively, in reconstituted enzymatic assays, using an intermediate of the demethylation reaction [32-3H]-3beta-hydroxylanost-7-en-32-ol as the substrate. Both enzymes gave similar type II spectra on titration with drugs, but a reduced affinity was observed for human CYP51 using the ability of carbon monoxide to displace the drug as a ligand and by calculation of IC50. However, although the results indicate higher affinity of the drugs for their target CYP51 in the major fungal pathogen C. albicans, when compared directly to CYP51 from humans, the difference was less than 10-fold. This difference is an order of magnitude lower than previously reported data based on measurements using unpurified human CYP51 enzyme preparations. Consequently, increased azole doses to combat resistant candidaemia may well inhibit endogenous human CYP51 and the potential consequences are discussed.

Lanosterol 14alpha-demethylase (CYP51) and spermatogenesis.

CYP51 is the only gene of the cytochrome P450 (P450, or CYP) superfamily that is expressed in prokaryotes and eukaryotes. In animals, the gene product, P45014DM, catalyzes the lanosterol 14alpha-demethylase reaction, an essential step in cholesterol biosynthesis. P45014DM serves a housekeeping role, and it was surprising to find the highest level of CYP51 expression in the testes. This is a result of very high-level CYP51 expression in postmeiotic, haploid spermatids and results in elevated P45014DM activity in these cells. It is proposed that the elevated level of 14alpha-demethylase activity leads to production of signaling sterols by haploid germ cells, although the function of such sterols in males is unknown.

The impact of a new emotional self-management program on stress, emotions, heart rate variability, DHEA and cortisol.

This study examined the effects on healthy adults of a new emotional self-management program, consisting of two key techniques, "Cut-Thru" and the "Heart Lock-In." These techniques are designed to eliminate negative thought loops and promote sustained positive emotional states. The hypotheses were that training and practice in these techniques would yield lowered levels of stress and negative emotion and cortisol, while resulting in increased positive emotion and DHEA levels over a one-month period. In addition, we hypothesized that increased coherence in heart rate variability patterns would be observed during the practice of the techniques. Forty-five healthy adults participated in the study, fifteen of whom acted as a comparison group for the psychological measures. Salivary DHEA/DHEAS and cortisol levels were measured, autonomic nervous system function was assessed by heart rate variability analysis, and emotions were measured using a psychological questionnaire. Individuals in the experimental group were assessed before and four weeks after receiving training in the self-management techniques. The experimental group experienced significant increases in the positive affect scales of Caring and Vigor and significant decreases in the negative affect scales of Guilt, Hostility, Burnout, Anxiety and Stress Effects, while no significant changes were seen in the comparison group. There was a mean 23 percent reduction in cortisol and a 100 percent increase in DHEA/DHEAS in the experimental group. DHEA was significantly and positively related to the affective state Warmheartedness, whereas cortisol was significantly and positively related to Stress Effects. Increased coherence in heart rate variability patterns was measured in 80 percent of the experimental group during the use of the techniques. The results suggest that techniques designed to eliminate negative thought loops can have important positive effects on stress, emotions and key physiological systems. The implications are that relatively inexpensive interventions may dramatically and positively impact individuals' health and well-being. Thus, individuals may have greater control over their minds, bodies and health than previously suspected.

Elevated expression of lanosterol 14alpha-demethylase (CYP51) and the synthesis of oocyte meiosis-activating sterols in postmeiotic germ cells of male rats.

Mammalian CYP51 encodes lanosterol 14alpha-demethylase (P45014DM) that is involved in the postsqualene part of cholesterol biosynthesis. This enzyme removes the 14alpha-methyl group from lanosterol and 24,25-dihydrolanosterol producing intermediates in cholesterol biosynthesis, the oocyte meiosis-activating sterols FF-MAS and MAS-412. Human and rat CYP51 messenger RNAs (mRNAs) are expressed in all tissues, with highest levels in the testis due to the presence of an additional shorter CYP51 transcript in this tissue. In situ hybridization shows the highest CYP51 mRNA levels in seminiferous tubules, with only background levels in Leydig cells. The rat testis-specific CYP51 mRNA arises from the use of an upstream polyadenylation site and is restricted to germ cells, being most abundant in elongating spermatids in stages VII-XIV, whereas somatic CYP51 transcripts are present in all cells. In contrast, the mRNA levels of squalene synthase are maximal in round spermatids, and no germ cell-specific transcript is observed. The rat male germ cell-specific CYP51 transcript is translated in vitro to two proteins of approximately 55 and 53.5 kDa. CYP51 activity is higher in protein extracts of testes and germ cells of sexually mature rats than in prepubertal animals, in which postmeiotic germ cells are not yet present. This shows increased capacity for the production of MAS sterols by male germ cells that have already completed meiosis, suggesting that they serve a role different from meiosis activation.

Structure and mapping of the human lanosterol 14alpha-demethylase gene (CYP51) encoding the cytochrome P450 involved in cholesterol biosynthesis; comparison of exon/intron organization with other mammalian and fungal CYP genes.

Sterol 14alpha-demethylase (P45014DM) encoded by CYP51 is a member of the cytochrome P450 (CYP) gene superfamily involved in sterol biosynthesis in fungi, plants, and animals. Constraints imposed by the specific function of CYP51 have severely limited sequence divergence in this family. Consequently, CYP51 is the only P450 family recognizable across all eukaryotic phyla. We have determined the structure of the functional human CYP51 gene, which spans 22 kb, is divided into 10 exons, and maps to 7q21.2-q21.3. The 5' portion of intron 1 is GC-rich and contains potential binding sites for several transcription factors. Primer extension studies reveal predominant transcription initiation sites in liver, kidney, lung, and placenta 250 and 249 bp upstream from the translation start site and a second major site at -100 bp. Ubiquitous expression of human CYP51 (Strömstedt et al., Arch. Biochem. Biophys. 329: 73-81, 1996), the absence of TATA and CAAT patterns, a GC-rich sequence in the promoter region, and initiation of CYP51 transcription at more than one site indicate that CYP51 is a housekeeping gene. The 5'-flanking region, exon 1, and a portion of intron 1 show the characteristics of a CpG island, with the observed/expected CpG ratio of 0.79. Sterol responsive element-like motifs were present in this region, suggesting regulation by oxysterols via a mechanism similar to that associated with other genes involved in cholesterol homeostasis. Comparison of the human CYP51 gene structure with structures of other mammalian and fungal CYP gene families shows that 7 of the 9 CYP51 introns are located at unique positions. More than 80 intron locations exist in mammalian and fungal CYP gene families, and it seems very unlikely that all these introns could have been present in the primordial CYP gene.

The three human cytochrome P450 lanosterol 14 alpha-demethylase (CYP51) genes reside on chromosomes 3, 7, and 13: structure of the two retrotransposed pseudogenes, association with a line-1 element, and evolution of the human CYP51 family.

The three human lanosterol 14 alpha-demethylase (CYP51) genes have been mapped to human chromosomes 3, 7, and 13 using a polychromosomal somatic cell hybrid panel. Two of the genes have been cloned from human chromosome 3-specific (CYP51P1) or from human chromosome 13-containing (CYP51P2) cell hybrids. Both were found to be processed pseudogenes, the first reported in the cytochrome P450 (CYP) gene superfamily. The functional CYP51 gene resides on human chromosome 7. CYP51P1 is 96.5% identical to the human CYP51 coding sequence and is not interrupted with introns but has six in-frame stop codons resulting from point mutations. The intronless CYP51P2 gene is 97.2% identical to the CYP51 cDNA coding region. It has a 1-bp insertion leading to a change of reading frame after codon 9 and a stop codon after amino acid 81. In addition, the CYP51P2 sequence is interrupted with a 5' truncated 131-bp LINE-1 element after nucleotide 606. The element belongs to the youngest LINE subfamily Sb and is 98.2% identical to the LINE-1 element expressed in human teratocarcinoma cells. CYP51 processed pseudogenes are the only known examples of the reverse flow of genetic information during evolution of the large (more than 480 genes) CYP superfamily, suggesting expression in the germ line and a housekeeping function of the lanosterol 14 alpha-demethylase gene. CYP51 pseudogenes evolved by two independent reverse transcription events of the human CYP51 mRNA approximately 9.5 MYR (CYP51P2) and approximately 11.7 MYR (CYP51P1) ago and were inactivated soon after the insertion. The truncated L1 element was inserted into CYP51P2 approximately 6 MYR ago.

The ubiquitously expressed human CYP51 encodes lanosterol 14 alpha-demethylase, a cytochrome P450 whose expression is regulated by oxysterols.

Sterol biosynthesis requires the removal of the 14 alpha-methyl group from lanosterol in animals and fungi and from obtusifoliol in plants. This reaction is catalyzed by a microsomal cytochrome P450, the sterol 14 alpha-demethylase (P450(14DM), which is the only P450 described so far to be expressed in different phyla. A cDNA encoding human P450(14DM) was isolated from a liver cDNA library using a partial rat lanosterol 14 alpha-demethylase cDNA probe. The deduced amino acid sequence is 93% and 38--42% identical to rat and fungal P450(14DM), respectively. Expression of the human CYP51 cDNA in Escherichia coli showed that the cDNA encodes an enzyme having lanosterol 14 alpha-demethylase activity. Northern blot analysis showed that CYP51 mRNA is ubiquitously expressed with highest levels in testis, ovary, adrenal, prostate, liver, kidney, and lung. Many genes involved in cholesterol homeostasis are regulated by cholesterol or its metabolites. In the case of CYP51, cholesterol deprivation led to a 2.6- to 3.8-fold induction of mRNA levels in human adrenocortical H295R cells and this effect was suppressed by the addition of 25-hydroxycholesterol. In human hepatoma HepG2 cells, no effect of cholesterol deprivation was observed; however, the levels of CYP51 mRNA were reduced 4- to 6-fold by the addition of 25-hydroxycholesterol. Thus, like several other genes in the cholesterol biosynthetic pathway, including the 3-hydroxy-3-methylglutaryl coenzyme A (HMG CoA) synthase, HMG CoA reductase, squalene synthase, and farnesyl diphosphate synthase, the expression of the human CYP51 is suppressed by oxysterols.

Progesterone metabolism by the filamentous fungus Cochliobolus lunatus.

Studies of Cochliobolus lunatus m118 steroid metabolism by thin-layer chromatography, mass spectrometry and NMR spectroscopy revealed that the fungus hydroxylates progesterone at positions 7 alpha, 11 beta and 14 alpha, and oxidizes the 11 beta-hydroxy group to the ketone. The 1H NMR spectra of two of the steroid metabolites, 11 beta,14 alpha-dihydroxyprogesterone and 11-oxo-14 alpha-hydroxyprogesterone, are reported for the first time. It is still not known if all the hydroxylation reactions are performed in C. lunatus by a single, non-specific, steroid hydroxylase, structurally different from the 11 beta-hydroxylase found in higher eucaryotes, or if different forms of the enzyme are involved.