Expression of homeobox genes during spermatogenesis

Gene transfer to mouse testes by electroporation and its influence on spermatogenesis

We transferred the adventitious gene pCAGGS-lacZ to mouse testes with the use of a square-wave electroporator and investigated the efficiency of gene transfer (GT) and the influence of the procedure on testicular damage and spermatogenesis. Mice were divided into 5 groups: (1-2) injection of gene/phosphate-buffered saline (PBS) into the interstitial space followed by electroporation (EP), (3) EP alone, (4-5) injection of gene/PBS without EP. The presence of the lacZ gene was determined by X-gal (5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside) staining and the polymerase chain reaction (PCR). The influence of transfer on spermatogenesis was assessed by evaluating the seminiferous tubules according to the Johnsen score (JS). TdT-mediated dUTP-biotin nick end-labeling (TUNEL) staining was performed for the detection of apoptosis in the testes to evaluate the testicular damage caused by GT, and fertilization ability was assessed by mating male mice from each group with normal female mice at 1, 2, 4, 6, and 8 weeks after the procedure. LacZ expression was detected by X-gal staining and PCR for 4 weeks after GT in group 1. But in group 4, LacZ expression was not detected for all times. In groups 1 through 3, the JSs decreased gradually until 4 weeks and recovered at 6 and 8 weeks after GT. The JSs were significantly decreased at 4 weeks for groups 1 through 3 compared with groups 4 and 5. In groups 1 through 3, apoptotic cells were significantly more numerous at 1, 2, and 4 weeks after the procedure, and there were significant differences in their numbers between groups 1 through 3 and groups 4 and 5 until 4 weeks after the procedure. The number of offspring did not differ significantly between all groups. These results suggest that although spermatogenic damage caused by EP could present problems, GT by EP might be effective for transfecting germ cells or somatic cells and could be applicable for in vivo gene therapy for male infertility in the future.

Comparison of two methods of in vivo gene transfer by electroporation

OBJECTIVE

To evaluate two contrasting methods of in vivo gene transfer into testicular cells using electroporation, with regard to efficiency of transfer and damage to the testes.

DESIGN

Controlled animal study.

SETTING

Research laboratory at a university medical school.

ANIMAL(S)

8-10-week-old male mice.

INTERVENTION(S)

The reporter construct pCAGGS-LacZ consisting of a cytomegalovirus enhancer/chicken beta-actin promoter attached to the LacZ gene was introduced into the testes in vivo using electroporation. For eight weeks, the efficiency and extent of LacZ gene expression, and the extent to which the testis was damaged by the technique, were investigated.

MAIN OUTCOME MEASURE(S)

Beta-galactosidase activity resulting from expression of the LacZ transgene was verified by X-gal staining, and LacZ mRNA expression was determined by RT-PCR analysis. Potential disorders associated with seminiferous tubular sperm formation were evaluated using the Johnsen score.

RESULT(S)

Long-lasting beta-galactosidase activity was detected in spermatogenic cells up to eight weeks postelectroporation. Apparent damage to spermatogenesis was evident but was transient in nature and recovered with time; this plasticity was particularly evident following rete testes injection.

CONCLUSION(S)

Injection into the rete testis appears to be more suitable for in vivo gene transfer by electroporation than direct intratesticular injection.

In vivo gene transfer to mouse spermatogenic cells using green fluorescent protein as a marker

Combination of the DNA injection into seminiferous tubules and the subsequent in vivo electroporation (EP) has become an efficient and convenient assay system for spermatogenic-specific gene expression during spermatogenesis of mice. In this study, we made methodological modifications to enhance the transfection efficiency, and evaluated the possibility of this technique to generate transgenic offspring using green fluorescent protein (GFP) as a marker. After the in vivo gene transfer, GFP expression could be monitored easily and repeatedly on the surface of the testis of live mice under fluorescent microscopy. The serial sections of the transfected testis revealed that transient expression of GFP was extended even in the innermost region of the testis uniformly, but confined to spermatogenic cells and Sertoli cells within the seminiferous tubules. Furthermore, long-lasting GFP expression could be detected in the spermatogenic cells even 2 months after EP. Natural mating with normal adult females revealed that 65% of the transfected males maintained fertilizable ability and could generate their offspring normally. Germ-line transmission of the GFP vector to the offspring was checked under fluorescent microscopy, but no transgenic offspring has been detected up to now. These results suggest that the application of additional techniques, such as cell sorting for GFP-positive germ cells followed by nuclear transfer to the oocytes, would make this method as a novel strategy for generating transgenic animals. J. Exp. Zool. 286:212-218, 2000.

Rhophilin, a small GTPase Rho-binding protein, is abundantly expressed in the mouse testis and localized in the principal piece of the sperm tail

Tissue distribution and cellular localization of rhophilin, a 71 kDa Rho-binding protein, were examined in mice. Rhophilin mRNA was highly expressed in adult testis, but was absent in the testis of W/WV mice deficient in germ cells. An anti-rhophilin antibody detected a band of an expected size in sperm extracts, which was enriched in the tail fraction. Immunofluorescence analysis revealed two lines of striated staining running in parallel in the principal piece of the sperm tail. These results suggest that rhophilin is expressed in germ cells and localized in the fibrous sheath of the sperm tail.

In vivo gene transfer to mouse spermatogenic cells by deoxyribonucleic acid injection into seminiferous tubules and subsequent electroporation

An in vivo gene transfer technique for living mouse testes was used to develop a novel transient expression assay system for transcriptional regulatory elements of spermatogenic specific genes. The combination of DNA injection into seminiferous tubules and subsequent in vivo electroporation resulted in an efficient and convenient assay system for gene expression during spermatogenesis. The transfer of the firefly luciferase reporting gene driven by the Protamine-1 (Prm-1) enhancer region revealed a significant increase in the activity of the reporter enzyme. Histochemical studies of the transfer of the lacZ gene driven by the Prm-1 enhancer showed specific lacZ expression only in haploid spermatid cells in adult testes, corresponding with the expression pattern of endogenous Prm-1. We were able to detect long-lasting transgene expression in the transfected spermatogenic cells. A group of spermatogenic differentiating cells maintained the transfected lacZ expression after more than 2 mo of transfection, suggesting that spermatogenic stem cells and/or spermatogonia could also incorporate foreign DNA and that the transgene could be transmitted to the progenitor cells derived from a transfected proliferating germ cell.

Genomic organization and identification of an enhancer element containing binding sites for multiple proteins in rat pituitary tumor-transforming gene

The rat pituitary tumor transforming gene (PTTG) genomic structure was characterized in this study. Northern blot analysis showed that PTTG mRNA is highly expressed in testicular cell lines. Transfection of testicular cell lines with fusion constructs containing various portions of PTTG 5'-flanking sequences linked to luciferase showed that at least 745 base-pair (bp(s)) 5'-flanking sequences are required for PTTG transcriptional activation. DNaseI footprinting assays indicated that nuclear protein(s) from testicular cell lines interacts with PTTG 5'-flanking sequence between -509 and -624 bp, including two consensus Sp1 binding sites. Western and Southwestern blot analysis showed that three nuclear proteins in addition to Sp1 protein specifically interact with this DNA sequence and that two of these proteins are testicular cell-specific. Deletion of this 115-bp sequence from PTTG promoter resulted in complete loss of promoter function. Site-directed mutagenesis within the Sp1 consensus sequences indicated that the Sp1 binding sites are not critical components of the enhancer sequence for PTTG trancriptional activation in testicular cell lines. Finally, the 115-bp enhancer sequence was shown to be able to activate transcription from a heterologous promoter. These results suggest that PTTG transcriptional activation in testicular cell lines involves interactions of multiple nuclear factors with the PTTG 5' enhancer sequence.

The Pem homeobox gene. Androgen-dependent and -independent promoters and tissue-specific alternative RNA splicing

The Pem gene encodes an atypical homeodomain protein, distantly related to Prd/Pax family members, that we demonstrate is regulated in a complex transcriptional and post-transcriptional manner. We show that the rat Pem genomic structure includes three 5'-untranslated (5'-UT) exons and four coding exons, three of which encode the homeodomain. Several alternatively spliced transcripts were identified, including one that skips an internal coding exon, enabling this mRNA to express a novel form of the Pem protein. Other alternatively spliced mRNAs were characterized that possess different 5'-UT regions, including a muscle-specific transcript. The different 5'-UT termini present in Pem transcripts conferred different levels of translatability in vitro. Two promoters containing multiple transcription initiation sites were identified: a distal promoter (Pd) in the first 5'-UT exon and a proximal promoter (Pp) located in the "intron" upstream of the first coding exon. The Pd was active in placenta, ovary, tumor cell lines, and to a lesser extent in skeletal muscle. In contrast, transcripts from the Pp were only detectable in testis and epididymis and were only expressed in epididymis in the presence of testosterone. To our knowledge no transcription factors have previously been identified that exhibit androgen-dependent expression in the epididymis.

Homeobox genes and male reproductive development

PURPOSE

Homeobox genes encode transcription factors that dictate developmental events in philogenetically diverse organisms. In comparison to what is known about their role in embryogenesis, we know very little concerning homeobox gene function in neonates or adults. In this communication, we review studies that address the possible role of homeobox genes in male reproductive development, a system active in neonate and adult animals.

METHODS

Studies have shown that many homeobox genes are expressed in germ cells of the testis, while less is known about the identity of homeobox genes expressed in somatic cells of the testis or epididymis. Hox homeobox genes display a pattern of expression in testis that is dependent on their paralogous and orthologous position within the Hox gene chromosome clusters. Other homeobox genes are expressed in the male reproductive system, including many POU and Prd/Pax homeobox gene family members. More recently, it has been shown that the orphan homeobox gene, Pem, originally isolated by subtraction hybridization on the basis of its differential expression in tumor cell lines, is selectively expressed in reproductive tissue. Alternatively spliced Pem transcripts accumulate in testis and epididymis that differ from those expressed in tumors and placenta. Pem transcripts accumulate postnatally in the epididymis in a developmentally regulated manner.

CONCLUSIONS

The highly regulated pattern of expression exhibited by many homeobox genes in the male reproductive system suggests that homeobox transcription factors may dictate developmental events in this system. However, future studies are needed to determine the specific functional roles homeobox genes in male reproductive development and spermatogenesis.

Cell interactions in testis development: overexpression of c-mos in spermatocytes leads to increased germ cell proliferation

Possible functions of the c-mos proto-oncogene during spermatogenesis were investigated through perturbations of its expression in transgenic mice. Two promoters, one from the pre-meiotic male germ cell-specific mouse phosphoglycerate kinase 2 gene, and the other from the post-meiotic male germ cell-specific rat RT7 gene were used to direct expression of c-mos. Northern blot analysis of testis RNA from transgenic PGK-c-mos mice indicated elevated levels of c-mos RNA in spermatocytes and spermatids compared to controls. No transgene expression was detected in any other tissue examined, suggesting that the mouse PGK2 promoter, like the previously used human PGK2 promoter, confers correct cell-specific expression onto c-mos. The promoter from a newly characterized rat gene, RT7, was shown to direct expression specific to post-meiotic spermatids. Transgenic mice carrying an RT7-lacZ construct displayed immunoreactive bacterial beta-galactosidase as well as enzyme activity in round spermatids. The cellular specificity for beta-galactosidase expression observed in RT7-lacZ transgenic animals was in agreement with endogenous RT7 transcript expression. Northern blot analysis of testis RNA of RT7-c-mos transgenic mice showed elevated levels of c-mos in spermatids, but not in other cells or tissues examined. Western blot analysis demonstrated elevated levels of p43c-mos in spermatids of both PGK-c-mos and RT7-c-mos transgenic animals, but only PGK-c-mos transgenics had increased p43c-mos levels in spermatocytes. Both RT7-c-mos and PGK-c-mos transgenic mice are fertile and show no tendency toward transformation. RT7-c-mos mice have no discernible phenotype associated with the c-mos overexpression in spermatids. However, PGK-c-mos transgenic males exhibited a significant increase in germ cell number, as determined by cell counts using total germ cells and germ cells fractionated by centrifugal elutriation. Because mitotic divisions of germ cells occur prior to PGK-c-mos transgene expression, our observations suggest that c-mos overexpression in spermatocytes causes an alteration in cell-cell interactions.

A testis-specific gene encoding a nuclear high-mobility-group box protein located in elongating spermatids

A cDNA encoding a DNA-binding protein has been isolated by screening a mouse testicular expression cDNA library with a concatemer of a 12-bp putative protein-binding element present in the promoter of the testis-specific gene PGK-2. Sequence analysis of the isolated cDNA indicated the presence of an open reading frame that encodes a protein with two conserved DNA-binding motifs known as the high-mobility-group (HMG) boxes. Northern (RNA) blot analysis demonstrated that expression of the gene is restricted to the postpuberal testis. The DNA-binding activity and sequence specificity of the recombinant HMG protein were confirmed by DNA mobility shift assay using the initial concatemer of the PGK-2 promoter element as a probe as well as the wild-type or mutated versions of the 12-bp element within its natural sequence context. Immunocytochemical staining of adult testis sections with polyclonal antisera recognizing this recombinant HMG protein demonstrated that it is located predominantly in the nuclei of elongated spermatids at steps 9 and 10. These results suggest that this novel HMG box protein gene may be involved in the regulation of gene expression of the haploid male genome. The gene from which the cDNA was derived has been termed testis-specific HMG (tsHMG).

A testis-specific gene encoding a nuclear high-mobility-group box protein located in elongating spermatids

A cDNA encoding a DNA-binding protein has been isolated by screening a mouse testicular expression cDNA library with a concatemer of a 12-bp putative protein-binding element present in the promoter of the testis-specific gene PGK-2. Sequence analysis of the isolated cDNA indicated the presence of an open reading frame that encodes a protein with two conserved DNA-binding motifs known as the high-mobility-group (HMG) boxes. Northern (RNA) blot analysis demonstrated that expression of the gene is restricted to the postpuberal testis. The DNA-binding activity and sequence specificity of the recombinant HMG protein were confirmed by DNA mobility shift assay using the initial concatemer of the PGK-2 promoter element as a probe as well as the wild-type or mutated versions of the 12-bp element within its natural sequence context. Immunocytochemical staining of adult testis sections with polyclonal antisera recognizing this recombinant HMG protein demonstrated that it is located predominantly in the nuclei of elongated spermatids at steps 9 and 10. These results suggest that this novel HMG box protein gene may be involved in the regulation of gene expression of the haploid male genome. The gene from which the cDNA was derived has been termed testis-specific HMG (tsHMG).