Corrado Spadafora

Sperm cells as vectors for introducing foreign DNA into eggs: Genetic transformation of mice

Mature mouse sperm cells incubated in an isotonic buffer with cloned DNA capture DNA molecules over a 15 min period. Spermatozoa incubated with pSV2CAT plasmid in either circular or linear form were used to fertilize mouse eggs in vitro. Sequences complementary to pSV2CAT were identified in approximately 30% of 250 progeny by Southern blotting. A genomic library was constructed from the DNA of a positive mouse. Three positive clones were identified and two adjacent HincII restriction fragments of 240 and 370 bp showed identical sequences to the corresponding fragments of the pSV2CAT plasmid. F1 progeny showed paternal and maternal transmission of the transgenes from founders. CAT gene expression was detected on tissues of adult F1 individuals, preferentially on tails and muscle. We conclude that transgenic mice can be obtained using sperm cells as foreign DNA vectors.

Sperm cells and foreign DNA: a controversial relation.

Sperm cells from a variety of species share the spontaneous ability to take up foreign DNA. That feature has been exploited to generate genetically modified animals with variable efficiency in different species. An unexpectedly large set of factors appears to modulate the interaction of sperm cells with exogeneous DNA. The binding is mediated by specific DNA-binding proteins and is antagonized by an inhibitory factor in the seminal fluid. A portion of sperm-bound DNA is internalized in nuclei, a process mediated by CD4 molecules. Sperm interaction with foreign DNA triggers endogenous nuclease(s) that cleaves both the exogenous and the genomic DNA, eventually leading to a cell death process which resembles apoptosis. Internalized foreign DNA sequences reach the nuclear matrix and undergo recombination with chromosomal DNA. From these studies, a surprising network of metabolic functions is beginning to emerge in mature spermatozoa, which are normally repressed and are specifically activated upon exposure to appropriate stimuli.

Inhibition of endogenous reverse transcriptase antagonizes human tumor growth.

Undifferentiated cells and embryos express high levels of endogenous non-telomerase reverse transcriptase (RT) of retroposon/retroviral origin. We previously found that RT inhibitors modulate cell growth and differentiation in several cell lines. We have now sought to establish whether high levels of RT activity are directly linked to cell transformation. To address this possibility, we have employed two different approaches to inhibit RT activity in melanoma and prostate carcinoma cell lines: pharmacological inhibition by two characterized RT inhibitors, nevirapine and efavirenz, and downregulation of expression of RT-encoding LINE-1 elements by RNA interference (RNAi). Both treatments reduced proliferation, induced morphological differentiation and reprogrammed gene expression. These features are reversible upon discontinuation of the anti-RT treatment, suggesting that RT contributes to an epigenetic level of control. Most importantly, inhibition of RT activity in vivo antagonized tumor growth in animal experiments. Moreover, pretreatment with RT inhibitors attenuated the tumorigenic phenotype of prostate carcinoma cells inoculated in nude mice. Based on these data, the endogenous RT can be regarded as an epigenetic regulator of cell differentiation and proliferation and may represent a novel target in cancer therapy.

Sperm-mediated gene transfer in mice

Sperm‐mediated DNA transfer to offspring has the potential to markedly simplify the generation of transgenic animals, but the efficiency in mice has been controversial. To determine the basis of the variability of the procedure in mice, we undertook a large, collaborative study of sperm‐mediated DNA transfer to mouse eggs in well‐established laboratory conditions for in vitro fertilization and offspring development following embryo transfer. Sperm were incubated with plasmid DNA during the capacitation period and then added to freshly ovulated mouse oocytes for fertilization; cleaved embryos were then transferred to the oviducts of pseudopregnant recipients for gestation. From a total of 75 experiments, 13 produced 130 transgenic offspring, amounting to 7.4% of total fetuses. In five experiments, more than 85% of offspring were transgenic, but the factors leading to this high success rate were not discovered. Clustering of such a low frequency event could account for the disparate reports of transgenic success with sperm‐mediated DNA transfer to mouse offspring. Discovering the factors important to success would not only allow this simplified approach to become an important tool in the generation of transgenic mice, but could also lead to important insights into natural protective mechanisms against sperm‐mediated transfer of foreign DNA. Mol. Reprod. Dev. 50:406–409, 1998.

Distinct roles for LINE-1 and HERV-K retroelements in cell proliferation, differentiation and tumor progression

Transformed cells express high levels of non-telomeric reverse-transcriptase (RT) activity of retrotransposon and endogenous retrovirus origin. We previously reported that RT inhibition, either pharmacological or through transient silencing of RT-encoding LINE-1 (L1) elements by RNA interference (RNAi), reduced proliferation, induced differentiation and reprogrammed gene expression in human tumorigenic cell lines. Moreover, the antiretroviral drug efavirenz antagonized tumor progression in animal models in vivo. To get insight into the role of retroelements in tumorigenesis, we have now produced two cell lines derived from A-375 melanoma, in which the expression of either L1 retrotransposon, or HERV-K endogenous retrovirus, was stably suppressed by RNAi. Compared to the parental A-375 cell line, cells with stably interfered L1 expression show a lower proliferation rate, a differentiated morphology and lower tumorigenicity when inoculated in nude mice. L1 silencing modulates expression of several genes and, unexpectedly, also downregulates HERV-K expression. In HERV-K interfered cells, instead, L1 expression was unaffected, and cell proliferation and differentiation remained unchanged compared to parental A-375 cells.In vivo, however, their tumorigenic potential was found to be reduced after inoculation in nude mice. These results suggest that L1 and HERV-K play specific and distinct roles in cell transformation and tumor progression.

Sperm‐mediated DNA transfer in bovine and swine species

Abstract Ejaculated sperm cells from both bovine and swine animals depleted of the seminal fluid were used as vectors for transferring different plasmid DNAs into eggs during the fertilization process. PCR screening of about 2000 blastocysts showed that transformed embryos were obtained in both animal species with varying efficiencies, and that the rate of transformation depended on the plasmid used. The most efficient rate was obtained in both species with the pSV2CAT construct, yielding 22% positive blastocysts in bovine and 5.7% in swine respectively. Artificial insemination of ten sows with boar sperm cells that had been preincubated with pSV2CAT DNA produced 82 offspring. Southern blot analysis of the DNAs extracted from the animal tails showed that five animals were transgenic and contained sequences complementary to pSV2CAT DNA that appeared to be rearranged compared to the original plasmid. These results indicate that sperm‐mediated DNA transfer protocols can be successfully adapted for the genera...

The activation of human endogenous retrovirus K (HERV-K) is implicated in melanoma cell malignant transformation

Melanoma development is a multi-step process arising from a series of genetic and epigenetic events. Although the sequential stages involved in progression from melanocytes to malignant melanoma are clearly defined, our current understanding of the mechanisms leading to melanoma onset is still incomplete. Growing evidence show that the activation of endogenous retroviral sequences might be involved in transformation of melanocytes as well as in the increased ability of melanoma cells to escape immune surveillance. Here we show that human melanoma cells in vitro undergo a transition from adherent to a more malignant, non-adherent phenotype when exposed to stress conditions. Melanoma-derived non-adherent cells are characterized by an increased proliferative potential and a decreased expression of both HLA class I molecules and Melan-A/MART-1 antigen, similarly to highly malignant cells. These phenotypic and functional modifications are accompanied by the activation of human endogenous retrovirus K expression (HERV-K) and massive production of viral-like particles. Down-regulation of HERV-K expression by RNA interference prevents the transition from the adherent to the non-adherent growth phenotype in low serum. These results implicate HERV-K in at least some critical steps of melanoma progression.

Exposure of normal and transformed cells to nevirapine, a reverse transcriptase inhibitor, reduces cell growth and promotes differentiation

Endogenous, nontelomeric reverse transcriptase (RT) is encoded by two classes of repeated elements: retrotransposons and endogenous retroviruses. Expression of RT-coding genes is generally repressed in differentiated nonpathological tissues, yet is active in the mammalian germ line, embryonic tissues and tumor cells. Nevirapine is a non-nucleoside RT inhibitor with a well-characterized inhibitory activity on RT enzymes of retroviral origin. Here, we show that nevirapine is also an effective inhibitor of the endogenous RT in murine and human cell lines. In addition, progenitor and transformed cells undergo a significant reduction in the rate of cell growth upon exposure to nevirapine. This is accompanied by the onset of differentiation, as depicted in F9 and C2C7 progenitor cells cultures in which nevirapine triggers the expression of differentiation-specific markers. Consistent with this, an extensive reprogramming of cell cycle gene expression was depicted in nevirapine-treated F9 cultures. Furthermore, nevirapine exposure rescued the differentiation block present in acute myeloid leukemia (AML) cell lines and primary blasts from two AML patients, as indicated by morphological, functional and immunophenotypic assays. The finding that an RT inhibitor can modulate cell proliferation and differentiation suggests that RT may represent a novel target in the development of therapeutical approaches to neoplasia.

Soma-to-Germline Transmission of RNA in Mice Xenografted with Human Tumour Cells: Possible Transport by Exosomes

Mendelian laws provide the universal founding paradigm for the mechanism of genetic inheritance through which characters are segregated and assorted. In recent years, however, parallel with the rapid growth of epigenetic studies, cases of inheritance deviating from Mendelian patterns have emerged. Growing studies underscore phenotypic variations and increased risk of pathologies that are transgenerationally inherited in a non-Mendelian fashion in the absence of any classically identifiable mutation or predisposing genetic lesion in the genome of individuals who develop the disease. Non-Mendelian inheritance is most often transmitted through the germline in consequence of primary events occurring in somatic cells, implying soma-to-germline transmission of information. While studies of sperm cells suggest that epigenetic variations can potentially underlie phenotypic alterations across generations, no instance of transmission of DNA- or RNA-mediated information from somatic to germ cells has been reported as yet. To address these issues, we have now generated a mouse model xenografted with human melanoma cells stably expressing EGFP-encoding plasmid. We find that EGFP RNA is released from the xenografted human cells into the bloodstream and eventually in spermatozoa of the mice. Tumor-released EGFP RNA is associated with an extracellular fraction processed for exosome purification and expressing exosomal markers, in all steps of the process, from the xenografted cancer cells to the spermatozoa of the recipient animals, strongly suggesting that exosomes are the carriers of a flow of information from somatic cells to gametes. Together, these results indicate that somatic RNA is transferred to sperm cells, which can therefore act as the final recipients of somatic cell-derived information.

A Role for Endogenous Reverse Transcriptase in Tumorigenesis and As a Target in Differentiating Cancer Therapy

An unexpected result emerging from completion of the genome sequencing project is that a large portion of mammalian genomes is constituted by retrotransposons. A large body of published data supports the conclusion that retrotransposons are biologically active elements and indicates that retrotransposition is an ongoing process in mammalian genomes. Retroelements can act as insertional mutagens altering the coding integrity of genes and, recently, have been found to also affect the expression of cellular genes at the epigenetic level: in this light, they are a potential threat in that these events can trigger the onset of several pathologies including cancer. Retroelement genes, and particularly the gene coding for reverse transcriptase (RT), are typically expressed at high levels in transformed cells and tumors. In recent work, we have found that drug‐mediated inhibition of the endogenous RT activity, or silencing of expression of active retrotransposons of the LINE‐1 family by RNA interference, down‐regulate cell growth and induce the activation of differentiating functions in several cancer cell lines. Moreover, the inhibition of endogenous RT activity in vivo antagonizes the growth of human tumors in animal models. In this review, we discuss newly emerging concepts on the role of retrotransposons and suggest that an abnormally high level of the RT activity that they encode may contribute to the loss of control in the proliferation and differentiation programs typical of transformed cells. In this light, RT‐coding elements may be regarded as promising targets in the development of novel, differentiation‐inducing approaches to cancer therapy.