Uterine RAC1 via Pak1-ERM signaling directs normal luminal epithelial integrity conducive to on-time embryo implantation in mice

Successful embryo implantation requires functional luminal epithelia to establish uterine receptivity and blastocyst-uterine adhesion. During the configuration of uterine receptivity from prereceptive phase, the luminal epithelium undergoes dynamic membrane reorganization and depolarization. This timely regulated epithelial membrane maturation and precisely maintained epithelial integrity are critical for embryo implantation in both humans and mice. However, it remained largely unexplored with respect to potential signaling cascades governing this functional epithelial transformation prior to implantation. Using multiple genetic and cellular approaches combined with uterine conditional Rac1 deletion mouse model, we demonstrated herein that Rac1, a small GTPase, is spatiotemporally expressed in the periimplantation uterus, and uterine depletion of Rac1 induces premature decrease of epithelial apical-basal polarity and defective junction remodeling, leading to disrupted uterine receptivity and implantation failure. Further investigations identified Pak1-ERM as a downstream signaling cascade upon Rac1 activation in the luminal epithelium necessary for uterine receptivity. In addition, we also demonstrated that Rac1 via P38 MAPK signaling ensures timely epithelial apoptotic death at postimplantation. Besides uncovering a potentially important molecule machinery governing uterine luminal integrity for embryo implantation, our finding has high clinical relevance, because Rac1 is essential for normal endometrial functions in women.

Analysis of SAFB1 and SAFB2 Knockout Mice Reveals Non-Redundant Functions of the Two Estrogen Receptor Co-Repressor Paralogs

The Scaffold Attachment Factor B1 (SAFB1) and B2 (SAFB2) have been shown to be involved in chromatin organization, transcriptional regulation, and RNA processing. The paralogs SAFB1 and SAFB2 share 74% similarity at the amino acid level, with up to 98% similarity in some functional domains. These functional domains include DNA and RNA-binding domains, and a C-terminal repression domain. We have previously shown that SAFB1 and SAFB2 function as estrogen receptor (ER) corepressors – they directly bind to ER, and repress its transcriptional activity. There is also evidence that both proteins play a role in breast cancer; their shared chromosomal locus on chromosome 19p13 displays high rates of LOH, and protein loss was associated with worse survival of breast cancer patients.To understand the roles of SAFB1 and SAFB2 in development and function of hormone responsive tissues, we generated gene-specific knockout (KO) mouse models. Deletion of SAFB1 resulted in a high degree of embryonic and perinatal lethality. Surviving SAFB1 KO mice displayed severe growth retardation associated with low serum IGF-I levels, male infertility and female subfertility. In contrast, SAFB2 KO mice were born at the expected Mendelian ratio and did not show any obvious defects in growth or fertility. Initial gross pathology analysis has not yet revealed any significant defects.Since the SAFB proteins are known to play a role in estrogen response, we analyzed mammary gland development in the two mouse models. Young virgin SAFB1 KO mice showed delayed mammary gland development with a significantly reduced number of terminal end buds and decreased outgrowth compared to wild type (WT) controls. This was likely a result of delayed puberty, due to low IGF-I levels, since at the four month time point, mammary gland growth was restored in the virgin SAFB1 KO mice to that seen in WT controls. Interestingly, the KO glands exhibited increased alveolar development and side branching. To measure proliferation directly, we performed mammary gland transplantation experiments, thereby excluding secondary effects due to systemic defects. These studies showed a significant increase in proliferation in SAFB1 KO glands compared to WT control glands. In contrast to the SAFB1-null mice, we did not observe any obvious mammary gland defects in pubertal or adult SAFB2-null mice. However, mammary glands from aged virgin SAFB2 mice (1.5 years old) showed extensive side branching and precocious development of alveolar buds resembling glands of late pregnant mice. This was associated with increased proliferation of alveolar cells in the SAFB2 KO glands.In summary, genetic ablation of the ER co-repressors SAFB1 and SAFB2 results in defects in mammary gland development. In general, the two mouse models have very different phenotypes, revealing diverse and non-redundant functions of SAFB1 and SAFB2, findings that were unexpected based on their high sequence similarity. We are currently performing additional studies to finalize characterization of the in vivo phenotypes, focusing on hormone responsive tissues, and also to understand the mechanism underlying the observed phenotypes.

Citation Information: Cancer Res 2009;69(24 Suppl):Abstract nr 2162.

Expression of an Nkx3.1-CRE gene using ROSA26 reporter mice

The genetic locus of Nkx3.1, an early murine marker of sclerotome and prostate development, was disrupted by a knock in of CRE recombinase via homologous recombination in embryonic stem cells. Cell fate mapping revealed previously unidentified cell lineages expanded from Nkx3.1-expressing cell populations and recapitulated reported Nkx3.1 expression patterns. In lineage trace experiments of E18.5 Nkx3.1-CRE; R26R embryos novel staining was observed in areas of the lungs, portions of the duodenum, and vertebral elements of the skeleton. beta-galactosidase activity measured in Nkx3.1-CRE; R26R and Nkx3.2-CRE; R26R embryos was observed in overlapping regions of the sclerotome but no apparent change in Nkx3.1 expression was seen in the Nkx3.2 mutants by in situ hybridization.

Functional and clinical characterization of a mutation in KCNJ2 associated with Andersen-Tawil syndrome

BACKGROUND

Andersen-Tawil syndrome (ATS) is a rare inherited disorder, characterised by periodic paralysis, cardiac dysarrhythmias, and dysmorphic features, and is caused by mutations in the gene KCNJ2, which encodes the inward rectifier potassium channel, Kir2.1. This study sought to analyse KCNJ2 in patients with familial ATS and to determine the functional characteristics of the mutated gene.

METHODS AND RESULTS

We screened a family with inherited ATS for the mutation in KCNJ2, using direct DNA sequencing. A missense mutation (T75R) of Kir2.1, located in the highly conserved cytoplasmic N-terminal domain, was identified in three affected members of this family. Using the Xenopus oocyte expression system and whole cell voltage clamp analyses, we found that the T75R mutant was non-functional and possessed a strong dominant negative effect when co-expressed with the same amount of wild type Kir2.1. Transgenic (Tg) mice expressing the mutated form of Kir2.1 in the heart had prolonged QTc intervals compared with mice expressing the wild type protein. Ventricular tachyarrhythmias were observed in 5 of 14 T75R-Tg mice compared with 1 of 7 Wt-Tg and none of 6 non-transgenic littermates. In three of five T75R-Tg mice with ventricular tachycardia, their ECG disclosed bidirectional tachycardia as in our proband.

CONCLUSIONS

The in vitro studies revealed that the T75R mutant of Kir2.1 had a strong dominant negative effect in the Xenopus oocyte expression system. It still preserved the ability to co-assemble and traffic to the cell membrane in mammalian cells. For in vivo studies, the T75R-Tg mice had bidirectional ventricular tachycardia after induction and longer QT intervals.

Embryonic expression of an Nkx2-5/Cre gene using ROSA26 reporter mice

Nkx2-5, one of the earliest cardiac-specific markers in vertebrate embryos, was used as a genetic locus to knock in the Cre recombinase gene by homologous recombination. Offspring resulting from heterozygous Nkx2-5/Cre mice mated to ROSA26 (R26R) reporter mice provided a model system for following Nkx2-5 gene activity by beta-galactosidase (beta-gal) activity. beta-gal activity was initially observed in the early cardiac crescent, cardiomyocytes of the looping heart tube, and in the epithelium of the first pharyngeal arch. In later stage embryos (10.5-13.5 days postcoitum, dpc), beta-gal activity was observed in the stomach and spleen, the dorsum of the tongue, and in the condensing primordium of the tooth. The Nkx2-5/Cre mouse model should provide a useful genetic resource to elucidate the role of loxP manipulated genetic targets in cardiogenesis and other developmental processes.

C/EBPalpha is required for differentiation of white, but not brown, adipose tissue

The transcription factor CCAAT enhancer binding protein alpha (C/EBPalpha) is expressed at high levels in liver and adipose tissue. Cell culture studies show that C/EBPalpha is sufficient to trigger differentiation of preadipocytes into mature adipocytes, suggesting a central role for C/EBPalpha in the development of adipose tissue. C/EBPalpha knockout mice die within 7-12 h after birth. Defective gluconeogenesis of the liver and subsequent hypoglycemia contribute to the early death of these animals. This short life span impairs investigation of the development of adipose tissue in these mice. To improve the survival of C/EBPalpha-/- animals, we generated a transgenic line that expresses C/EBPalpha under the control of the albumin enhancer/promoter. This line was bred into the knockout strain to generate animals that express C/EBPalpha in the liver but in no other tissue. The presence of the transgene improved survival of C/EBPalpha-/- animals almost 3-fold. Transgenic C/EBPalpha-/- animals at 7 days of age show an absence of s.c., perirenal, and epididymal white fat despite excess lipid substrate in the serum, whereas brown adipose tissue is somewhat hypertrophied and shows minimal biochemical alterations. Interestingly, mammary gland fat tissue is present and exhibits normal morphology. The absence of white adipose tissue in many depots in the presence of high serum lipid levels shows that C/EBPalpha is required for the in vivo development of this tissue. In contrast, brown adipose tissue differentiation is independent of C/EBPalpha expression. The presence of lipid in brown adipose tissue serves as an internal nutritional control, indicating that neither nutritional intake nor lipoprotein composition is likely responsible for the absence of white fat.

Insight into the physiological function(s) of uteroglobin by gene-knockout and antisense-transgenic approaches

To determine the physiological function(s) of uteroglobin (UG), a steroid-inducible, homodimeric, secreted protein, we have generated transgenic mice that either are completely UG-deficient due to UG gene-knockout (UG-KO) or are partially UG-deficient due to the expression of UG antisense RNA (UG-AS). Both the UG-KO and UG-AS mice develop immunoglobulin A (IgA) nephropathy (IgAN), characterized by microhematuria, albuminuria, and renal glomerular deposition of IgA, fibronectin (Fn), collagen, and C3 complement. This phenotype of both UG-KO and UG-AS mice is virtually identical to that of human IgAN, the most common primary glomerulopathy worldwide. The molecular mechanism by which UG prevents this disease in mice appears to center around UG's interaction with Fn. Since Fn, IgA, and UG are present in circulation and high plasma levels of IgA-Fn complex have been reported in human IgAN, we sought to determine whether UG interacts with Fn and prevents Fn-Fn and/or IgA-Fn interactions, essential for abnormal tissue deposition of Fn and IgA. Our coimmunoprecipitation studies uncovered the formation of Fn-UG heteromers in vitro and these heteromers are detectable in the plasma of normal mice, but not UG-KO mice. Further, high plasma levels of IgA-Fn complex, a characteristic of human IgAN patients, were also found in UG-KO mice. Finally, coadministration of UG + Fn or UG + IgA to UG-KO mice prevented glomerular deposition of Fn and IgA, respectively. Our results define a possible molecular mechanism of IgAN and provide insight into at least one important physiological function of UG in maintaining normal renal function in mice.

The role of CC10 in pulmonary carcinogenesis: from a marker to tumor suppression

CC10 is infrequently expressed in human non-small cell lung cancers (NSCLCs), despite being abundantly produced by progenitor cells for normal and neoplastic epithelium. Many abnormalities in the surrounding lung associated with field carcinogenesis, which reflect prolonged exposure to such carcinogens as tobacco smoke, also revealed altered expression of CC10. Exposure of hamsters and mice to the tobacco-specific carcinogen NNK led to reduced CC10 expression, which was partially reversible. Overexpression of CC10 in immortalized bronchial epithelial cells delayed the induction of anchorage-independent growth in response to NNK. The data suggest that downregulation of CC10 contributes to carcinogenesis because CC10 antagonizes the neoplastic phenotype.

Genomic organization, chromosomal localization, and expression of the murine RAB3D gene

Rab proteins, members of the Ras superfamily of small GTPases, play regulatory roles in intercompartmental vesicular transport. Each step of traffic seems to require the participation of at least one distinct Rab, with the Rab3 subfamily involved in stimulated exocytosis. We report our studies on the murine rab3D gene, one of the four mammalian Rab3 isoforms. We located this gene on chromosome 13, region A(2-3). The rab3D gene consists of 5 exons spanning 10.6 kb, and the structural gene is contained in exons 2 through 5 with one canonical GTP-binding motif in each exon. Organization of the rab3D gene is identical to that of rab3A but different from other rab genes. Alternative poly-A(+) signals in the 3' untranslated region account for the identities of multiple transcripts detected by Northern blot analysis. Rab3D is expressed in all tissues studied, predominantly in heart, lung, and liver, and binding sites for multiple transcription factors are found in the TATA-less promoter region.

Chk1 is an essential kinase that is regulated by Atr and required for the G(2)/M DNA damage checkpoint

Chk1, an evolutionarily conserved protein kinase, has been implicated in cell cycle checkpoint control in lower eukaryotes. By gene disruption, we show that CHK1 deficiency results in a severe proliferation defect and death in embryonic stem (ES) cells, and peri-implantation embryonic lethality in mice. Through analysis of a conditional CHK1-deficient cell line, we demonstrate that ES cells lacking Chk1 have a defective G(2)/M DNA damage checkpoint in response to gamma-irradiation (IR). CHK1 heterozygosity modestly enhances the tumorigenesis phenotype of WNT-1 transgenic mice. We show that in human cells, Chk1 is phosphorylated on serine 345 (S345) in response to UV, IR, and hydroxyurea (HU). Overexpression of wild-type Atr enhances, whereas overexpression of the kinase-defective mutant Atr inhibits S345 phosphorylation of Chk1 induced by UV treatment. Taken together, these data indicate that Chk1 plays an essential role in the mammalian DNA damage checkpoint, embryonic development, and tumor suppression, and that Atr regulates Chk1.

The oncoprotein kinase chaperone CDC37 functions as an oncogene in mice and collaborates with both c-myc and cyclin D1 in transformation of multiple tissues

CDC37 encodes a 50-kDa protein that targets intrinsically unstable oncoprotein kinases including Cdk4, Raf-1, and v-src to the molecular chaperone Hsp90, an interaction that is thought to be important for the establishment of signaling pathways. CDC37 is required for proliferation in budding yeast and is coexpressed with cyclin D1 in proliferative zones during mouse development, a finding consistent with a positive role in cell proliferation. CDC37 expression may not only be required to support proliferation in cells that are developmentally programmed to proliferate but may also be required in cells that are inappropriately induced to initiate proliferation by oncogenes. Here we report that mouse mammary tumor virus (MMTV)-CDC37 transgenic mice develop mammary gland tumors at a rate comparable to that observed previously in MMTV-cyclin D1 mice. Moreover, CDC37 was found to collaborate with MMTV-c-myc in the transformation of multiple tissues, including mammary and salivary glands in females and testis in males, and also collaborates with cyclin D1 to transform the female mammary gland. These data indicate that CDC37 can function as an oncogene in mice and suggests that the establishment of protein kinase pathways mediated by Cdc37-Hsp90 can be a rate-limiting event in epithelial cell transformation.

Induction of human Cdc37 in prostate cancer correlates with the ability of targeted Cdc37 expression to promote prostatic hyperplasia

The Cdc37 gene encodes a 50 kDa protein which targets intrinsically unstable oncoprotein kinases such as Cdk4, Raf-1, and src to the molecular chaperone Hsp90. This activity is thought to play an important role in the establishment of signaling pathways controlling cell proliferation. The budding yeast Cdc37 homolog is required for cell division and mammalian Cdc37 is expressed in proliferative zones during embryonic development and in adult tissues, consistent with a positive role in proliferation. Here we report that human prostatic tumors, neoplasias and certain pre-malignant lesions display increased Cdc37 expression, suggesting an important and early role for Cdc37 in prostatic transformation. To test the consequences of increased Cdc37 levels, transgenic mice expressing Cdc37 in the prostate were generated. These mice displayed a wide range of growth-related abnormalities including prostatic epithelial cell hyperplasia and dysplasia. These data suggest that the expression of Cdc37 may promote inappropriate proliferation and may be an important early step in the development of human prostate cancer.

Sur1 knockout mice. A model for K(ATP) channel-independent regulation of insulin secretion

Sur1 knockout mouse beta-cells lack K(ATP) channels and show spontaneous Ca(2+) action potentials equivalent to those seen in patients with persistent hyperinsulinemic hypoglycemia of infancy, but the mice are normoglycemic unless stressed. Sur1(-/-) islets lack first phase insulin secretion and exhibit an attenuated glucose-stimulated second phase secretion. Loss of the first phase leads to mild glucose intolerance, whereas reduced insulin output is consistent with observed neonatal hyperglycemia. Loss of K(ATP) channels impairs the rate of return to a basal secretory level after a fall in glucose concentration. This leads to increased hypoglycemia upon fasting and contributes to a very early, transient neonatal hypoglycemia. Whereas persistent hyperinsulinemic hypoglycemia of infancy underscores the importance of the K(ATP)-dependent ionic pathway in control of insulin release, the Sur1(-/-) animals provide a novel model for study of K(ATP)-independent pathways that regulate insulin secretion.

Decreased left ventricular ejection fraction in transgenic mice expressing mutant cardiac troponin T-Q(92), responsible for human hypertrophic cardiomyopathy

The causality of mutant sarcomeric proteins in hypertrophic cardiomyopathy (HCM) is well established. The current emphasis is to elucidate the pathogenesis of HCM in transgenic animal models. We determined the left ventricular ejection fraction (LVEF) in transgenic mice expressing mutant cardiac troponin T (cTnT)-Q(92), known to cause HCM in humans. Transgenes were constructed by placing wild-type (R(92)) or mutant (Q(92)) full-length human cTnT cDNAs 3' into a 5.5-kb murine [alpha -myosin heavy chain (MyHC)] promoter injected into fertilized zygotes. Three wild-type and six mutant lines were produced. Transgene mRNA and proteins, detected using transgene-specific probes were expressed at high levels in all wild-type and three mutant lines. The total cTnT mRNA pool was increased by up to five-fold in transgenic mice, but the total cTnT protein remained unchanged. The mean values of LVEF, determined by(178)Ta radionuclide angiography, were 57.8+/-6% (n=4) in non-transgenic littermate (NLM), 53.3+/-10 (n=6) in wild-type and 39. 4+/-6 (n=5) in mutant transgenic mice (P=0.009). The heart/body weight ratios and the number of cells stained with terminal deoxynucleotidyl transferase (TdT)-mediated nick end-labeling were similar among the groups. Three mutant mice had myocyte disarray and excess interstitial collagen and two had normal myocardial structure despite having reduced LVEF. Thus, in vivo expression of the mutant cTnT-Q(92)protein, responsible for human HCM, impaired global cardiac systolic function in transgenic mice, which also occurred in the absence of myocyte disarray and increased interstitial collagen.

A transgenic rabbit model for human hypertrophic cardiomyopathy

Certain mutations in genes for sarcomeric proteins cause hypertrophic cardiomyopathy (HCM). We have developed a transgenic rabbit model for HCM caused by a common point mutation in the beta-myosin heavy chain (MyHC) gene, R400Q. Wild-type and mutant human beta-MyHC cDNAs were cloned 3' to a 7-kb murine beta-MyHC promoter. We injected purified transgenes into fertilized zygotes to generate two lines each of the wild-type and mutant transgenic rabbits. Expression of transgene mRNA and protein were confirmed by Northern blotting and 2-dimensional gel electrophoresis followed by immunoblotting, respectively. Animals carrying the mutant transgene showed substantial myocyte disarray and a 3-fold increase in interstitial collagen expression in their myocardia. Mean septal thicknesses were comparable between rabbits carrying the wild type transgene and their nontransgenic littermates (NLMs) but were significantly increased in the mutant transgenic animals. Posterior wall thickness and left ventricular mass were also increased, but dimensions and systolic function were normal. Premature death was more common in mutant than in wild-type transgenic rabbits or in NLMs. Thus, cardiac expression of beta-MyHC-Q(403) in transgenic rabbits induced hypertrophy, myocyte and myofibrillar disarray, interstitial fibrosis, and premature death, phenotypes observed in humans patients with HCM due to beta-MyHC-Q(403).

Progesterone receptors in the thymus are required for thymic involution during pregnancy and for normal fertility

Thymocyte development is reported to be inhibited by pregnancy, although the impact of this effect on fertility is unknown. We demonstrate, using progesterone receptor null mutant mice, that the inhibitory effects of pregnancy hormones on T cell development require the presence of functional progesterone receptor (PR). A combination of hysterectomy, thymic immunohistochemistry, and transplant studies reveals that local expression of PR in thymic stromal cells is specifically required for thymic involution to occur. These cells, under the influence of progesterone, block T cell development at the early pre-T cell (CD3(-)CD44(+) CD25(+)) stage of development via a paracrine mechanism. In addition, age-related thymic involution is shown to occur by a separate PR-independent mechanism. Finally, pregnancy studies with thymic transplants from progesterone receptor null mutant mice to wild-type female recipients demonstrate that thymic stromal PR is required for normal fertility. Together, these observations provide evidence for a PR-dependent paracrine mechanism that blocks very early T cell lymphopoiesis during pregnancy and is essential for normal fertility.

Uteroglobin is essential in preventing immunoglobulin A nephropathy in mice

The molecular mechanism(s) of immunoglobulin A (IgA) nephropathy, the most common primary renal glomerular disease worldwide, is unknown. Its pathologic features include hematuria, high levels of circulating IgA-fibronectin (Fn) complexes, and glomerular deposition of IgA, complement C3, Fn and collagen. We report here that two independent mouse models (gene knockout and antisense transgenic), both manifesting deficiency of an anti-inflammatory protein, uteroglobin (UG), develop almost all of the pathologic features of human IgA nephropathy. We further demonstrate that Fn-UG heteromerization, reported to prevent abnormal glomerular deposition of Fn and collagen, also abrogates both the formation of IgA-Fn complexes and their binding to glomerular cells. Moreover, UG prevents glomerular accumulation of exogenous IgA in UG-null mice. These results define an essential role for UG in preventing mouse IgA nephropathy and warrant further studies to determine if a similar mechanism(s) underlies the human disease.

Overexpression of IGF-I in skeletal muscle of transgenic mice does not prevent unloading-induced atrophy

This study examined the association between local insulin-like growth factor I (IGF-I) overexpression and atrophy in skeletal muscle. We hypothesized that endogenous skeletal muscle IGF-I mRNA expression would decrease with hindlimb unloading (HU) in mice, and that transgenic mice overexpressing human IGF-I (hIGF-I) specifically in skeletal muscle would exhibit less atrophy after HU. Male transgenic mice and nontransgenic mice from the parent strain (FVB) were divided into four groups (n = 10/group): 1) transgenic, weight-bearing (IGF-I/WB); 2) transgenic, hindlimb unloaded (IGF-I/HU); 3) nontransgenic, weight-bearing (FVB/WB); and 4) nontransgenic, hindlimb unloaded (FVB/HU). HU groups were hindlimb unloaded for 14 days. Body mass was reduced (P < 0.05) after HU in both IGF-I (-9%) and FVB mice (-13%). Contrary to our hypothesis, we found that the relative abundance of mRNA for the endogenous rodent IGF-I (rIGF-I) was unaltered by HU in the gastrocnemius (GAST) muscle of wild-type FVB mice. High-level expression of hIGF-I peptide and mRNA was confirmed in the GAST and tibialis anterior (TA) muscles of the transgenic mice. Nevertheless, masses of the GAST and TA muscles were reduced (P < 0.05) in both FVB/HU and IGF-I/HU groups compared with FVB/WB and IGF-I/WB groups, respectively, and the percent atrophy in mass of these muscles did not differ between FVB and IGF-I mice. Therefore, skeletal muscle atrophy may not be associated with a reduction of endogenous rIGF-I mRNA level in 14-day HU mice. We conclude that high local expression of hIGF-I mRNA and peptide in skeletal muscle alone cannot attenuate unloading-induced atrophy of fast-twitch muscle in mice.

Cloning of the mouse SSTR5 gene

Five somatostatin receptor subtypes (SSTR1-5) have been recently cloned in different mammalian species. To date the mouse SSTR5 gene has not been cloned. Cloning and characterization of these genes allows for molecular analysis of receptor expression and function. Since the mouse has become a mammalian model that is permissive for genetic manipulation, the purpose of this study was to clone and characterize the mouse SSTR5 to investigate the molecular mechanisms of this receptor subtype. The gene was cloned by screening the mouse 129SvJ genomic library with a PCR-amplified probe from the 5' end of the mouse SSTR2 gene. The probe corresponded to the first 210 amino acids spanning from the amino terminal through the fourth transmembrane domain of the SSTR2 receptor. The primary screening generated 22 positive clones. During secondary and tertiary library screening 3 positive clones with the same restriction endonuclease digestive pattern were isolated. The nucleotide sequence of 1 clone was identified using a DNA sequencing technique. The sequence obtained was analyzed using the Basic Local Alignment Search Tool, which performs fast database searching combined with rigorous statistics for judging the significance of matched sequences. The result of this analysis showed that the sequence identified had 92% homology with the rat SSTR5 and 80% homology with the human SSTR5, which suggests that the cloned gene represents the mouse 129SvJ SSTR5 gene. In conclusion the mouse SSTR5 gene was successfully cloned. This gene will be important for use in gene regulation and gene ablation studies to determine the molecular events controlled by SSTR5 in regulating murine physiology and development.

Severe fibronectin-deposit renal glomerular disease in mice lacking uteroglobin

Despite myriads of biological activities ascribed to uteroglobin (UG), a steroid-inducible secreted protein, its physiological functions are unknown. Mice in which the uteroglobin gene was disrupted had severe renal disease that was associated with massive glomerular deposition of predominantly multimeric fibronectin (Fn). The molecular mechanism that normally prevents Fn deposition appears to involve high-affinity binding of UG with Fn to form Fn-UG heteromers that counteract Fn self-aggregation, which is required for abnormal tissue deposition. Thus, UG is essential for maintaining normal renal function in mice, which raises the possibility that an analogous pathogenic mechanism may underlie genetic Fn-deposit human glomerular disease.

Myogenic vector expression of insulin-like growth factor I stimulates muscle cell differentiation and myofiber hypertrophy in transgenic mice

The avian skeletal alpha-actin gene was used as a template for construction of a myogenic expression vector that was utilized to direct expression of a human IGF-I cDNA in cultured muscle cells and in striated muscle of transgenic mice. The proximal promoter region, together with the first intron and 1.8 kilobases of 3'-noncoding flanking sequence of the avian skeletal alpha-actin gene directed high level expression of human insulin-like growth factor I (IGF-I) in stably transfected C2C12 myoblasts and transgenic mice. Expression of the actin/IGF-I hybrid gene in C2C12 muscle cells increased levels of myogenic basic helix-loop-helix factor and contractile protein mRNAs and enhanced myotube formation. Expression of the actin/IGF-I hybrid gene in mice elevated IGF-I concentrations in skeletal muscle 47-fold resulting in myofiber hypertrophy. IGF-I concentrations in serum and body weight were not increased by transgene expression, suggesting that the effects of transgene expression were localized. These results indicate that sustained overexpression of IGF-I in skeletal muscle elicits myofiber hypertrophy and provides the basis for manipulation of muscle physiology utilizing skeletal alpha-actin-based vectors.

Prostate cancer in a transgenic mouse

Progress toward understanding the biology of prostate cancer has been slow due to the few animal research models available to study the spectrum of this uniquely human disease. To develop an animal model for prostate cancer, several lines of transgenic mice were generated by using the prostate-specific rat probasin promoter to derive expression of the simian virus 40 large tumor antigen-coding region. Mice expressing high levels of the transgene display progressive forms of prostatic disease that histologically resemble human prostate cancer, ranging from mild intraepithelial hyperplasia to large multinodular malignant neoplasia. Prostate tumors have been detected specifically in the prostate as early as 10 weeks of age. Immunohistochemical analysis of tumor tissue has demonstrated that dorsolateral prostate-specific secretory proteins were confined to well-differentiated ductal epithelial cells adjacent to, or within, the poorly differentiated tumor mass. Prostate tumors in the mice also display elevated levels of nuclear p53 and a decreased heterogeneous pattern of androgen-receptor expression, as observed in advanced human prostate cancer. The establishment of breeding lines of transgenic mice that reproducibly develop prostate cancer provides an animal model system to study the molecular basis of transformation of normal prostatic cells and the factors influencing the progression to metastatic prostate cancer.

Targeted developmental overexpression of calmodulin induces proliferative and hypertrophic growth of cardiomyocytes in transgenic mice

Calmodulin (CaM) levels are developmentally regulated in the mouse heart. During late gestational and early postnatal stages, CaM levels decline several-fold in close temporal association with the declining population of proliferating cardiomyocytes. This correlation suggests that CaM may influence cardiomyocyte cell cycle activity, particularly since CaM is implicated in cell cycle control in several eukaryotic nonmuscle cells. To test this possibility, nucleotides -500 to 77 of the human atrial natriuretic factor gene were linked to a chicken CaM minigene to establish two pedigrees of transgenic mice that express 3- to 5-fold increased levels of CaM in cardiomyocytes. Developmental overexpression of CaM in mouse cardiomyocytes produced a markedly exaggerated cardiac growth response, characterized by the presence of cardiomyocyte hypertrophy in regions demonstrated to overexpress CaM and by cardiomyocyte hyperplasia, apparent at early developmental stages. Early postnatal suppression of fusion gene expression in the cardiac ventricles correlated with regression of the ventricular growth response in transgenic relative to nontransgenic mice between 3 days and 6-10 weeks of age, but was not apparent in the cardiac atria, where levels of CaM remained constitutively elevated until advanced stages. To test the possibility that increased cytosolic Ca2+ buffering contributes to the growth response induced by CaM over-expression, two additional lines of transgenic mice were generated using the same human atrial natriuretic factor promoter to target expression of a CaM mutant (amino acids 75-82 deleted) in cardiomyocytes. This mutant has previously been shown to bind Ca2+ with kinetic properties similar to those of wild-type CaM, but was unable to activate several CaM-dependent target enzymes in vitro. Despite high level expression of the CaM mutant, no growth response was apparent in the hearts of transgenic relative to those of nontransgenic mice, suggesting that increased Ca2+ buffering is unlikely to contribute to the growth response induced by CaM overexpression. Taken together, these findings reveal that cardiomyocyte growth regulation is specifically influenced by CaM concentrations in transgenic mice.

The human osteocalcin promoter directs bone-specific vitamin D-regulatable gene expression in transgenic mice

Osteocalcin is a major noncollagenous protein of bone regulated by 1,25-dihydroxyvitamin D3 [1,25-(OH)2D3] and is believed to be expressed only by differentiated osteoblasts. We introduced a 3.9-kilobase human osteocalcin gene promoter (hOCP)-chloramphenicol acetyltransferase (CAT) fusion gene into the germ line of mice. Examination of tissue extracts from these transgenic mice demonstrated that the expression of CAT was restricted to bone-associated tissues and the brain. Immunohistochemical staining of femur tissue sections using CAT antibodies localized the production of CAT protein to osteoblasts and maturing chondrocytes. Previous studies via transient transfection into osteoblast-like cells have identified a vitamin D response element approximately 500 basepairs up-stream of the hOCP capable of mediating 1,25-(OH)2D3 induction. As a consequence, regulation of the transgene was examined in homozygous transgenic lines for sensitivity to 1,25-(OH)2D3. Hormonal deficiency was created using a low calcium diet supplemented with 0.8% SrCl2 for 7 days and was restored in experimental mice by injection of 25 ng 1,25-(OH)2D3/day, ip, for 3 days. The low vitamin D3 diet decreased CAT activity several-fold in extracts from calvaria, femur, and brain compared to that in mice maintained on a normal diet, while 1,25-(OH)2D3 supplementation restored and enhanced CAT activity over control values. These data demonstrate that hOCP is sufficient to direct osteoblast-specific 1,25-(OH)2D3-sensitive gene expression in mice in addition to the unexpected regulatable expression in brain tissue.

Targeting of gene expression to skeletal and cardiac muscle of trangenic animals

The tissue restricted and developmental potentiation of transcription by chicken alpha-skeletal actin promoter regions fused to the reporter gene chloramphenicol acetyl transferase (CAT) were characterized in transgenic mice. Six of eight expressing transgenic mouse lines containing the chicken alpha-skeletal actin promoter fused to CAT resulted in preferential transgene transcription in skeletal muscle tissue, similar to the endogenous mouse alpha-skeletal actin gene. Two of the eight lines departed from the preferred pattern of skeletal muscle expression with primary expression of the transgene in the heart, a tissue containing primarily cardiac actin isoforms. Developmentally, a transition from embryonic heart to fetal and neonatal skeletal muscle expression was produced by the transgene promoter, a pattern of regulation similar to that of the endogenous alpha-skeletal actin gene. Instances of departure of transgene expression from the endogenous gene implied the existance of higher order muscle gene regulatory mechanisms.