Striking heterogeneity of somatic L1 retrotransposition in single normal and cancerous gastrointestinal cells.

Somatic LINE-1 (L1) retrotransposition has been detected in early embryos, adult brains, and the gastrointestinal (GI) tract, and many cancers, including epithelial GI tumors. We previously found numerous somatic L1 insertions in paired normal and GI cancerous tissues. Here, using a modified method of single-cell analysis for somatic L1 insertions, we studied adenocarcinomas of colon, pancreas, and stomach, and found a variable number of somatic L1 insertions in tumors of the same type from patient to patient. We detected no somatic L1 insertions in single cells of 5 of 10 tumors studied. In three tumors, aneuploid cells were detected by FACS. In one pancreatic tumor, there were many more L1 insertions in aneuploid than in euploid tumor cells. In one gastric cancer, both aneuploid and euploid cells contained large numbers of likely clonal insertions. However, in a second gastric cancer with aneuploid cells, no somatic L1 insertions were found. We suggest that when the cellular environment is favorable to retrotransposition, aneuploidy predisposes tumor cells to L1 insertions, and retrotransposition may occur at the transition from euploidy to aneuploidy. Seventeen percent of insertions were also present in normal cells, similar to findings in genomic DNA from normal tissues of GI tumor patients. We provide evidence that: 1) The number of L1 insertions in tumors of the same type is highly variable, 2) most somatic L1 insertions in GI cancer tissues are absent from normal tissues, and 3) under certain conditions, somatic L1 retrotransposition exhibits a propensity for occurring in aneuploid cells.

Mobile DNA in Endocrinology: LINE-1 Retrotransposon Causing Partial Androgen Insensitivity Syndrome.

CONTEXT: Androgen insensitivity syndrome (AIS) is the most common cause of disorders of sex development in 46,XY individuals. It is an X-linked condition usually caused by pathogenic allelic variants in the androgen receptor (AR) gene. The phenotype depends on the AR variant, ranging from severe undervirilization (complete AIS) to several degrees of external genitalia undervirilization. Although 90% of those with complete AIS will have AR mutations, this will only be true for 40% of those with partial AIS (PAIS). OBJECTIVE: To identify the genetic etiology of AIS in a large multigenerational family with the PAIS phenotype. PARTICIPANTS: Nine affected individuals with clinical and laboratory findings consistent with PAIS and a normal exonic AR sequencing. SETTINGS: Endocrine clinic and genetic institute from two academic referral centers. DESIGN: Analysis of whole exons of the AR gene, including splicing regions, was performed, followed by sequencing of the 5'untranslated region (UTR) of the AR gene. Detailed phenotyping was performed at the initial diagnosis and long-term follow-up, and circulating levels of steroid gonadal hormones were measured in all affected individuals. AR expression was measured using RT-PCR and cultured fibroblasts. RESULTS: All 46,XY family members with PAIS had inherited, in hemizygosity, a complex defect (∼1100 bp) in the 5'UTR region of the AR surrounded by a duplicated 18-bp sequence (target site duplication). This sequence is 99.7% similar to an active, long, interspersed element present on the X chromosome (AC002980; Xq22.2), which was inserted in the 5'UTR of the AR gene, severely reducing AR expression and leading to PAIS. CONCLUSION: The molecular diagnosis of PAIS remains challenging. The genomic effect of retrotransposon mobilization should be considered a possible molecular cause of AIS and other AR diseases.

Emulsion Polymerization with a Biosurfactant.

Emulsion polymerization of styrene was conducted using a biosurfactant (i.e., sodium surfactin, hereinafter called just "surfactin") having very low critical micelle concentration (CMC, 2.9 × 10-3 mmol/L) and biodegradability characteristics. The nucleation mechanism was investigated by comparing with a conventional surfactant (i.e., sodium dodecyl sulfate) system. Unlike the emulsion polymerization systems using conventional surfactants, nucleation mechanisms changed above CMC in the presence of a biosurfactant. At low concentrations of surfactin (above CMC), the polystyrene (PS) particles are likely generated via a soap-free emulsion polymerization mechanism. In contrast, at high surfactin concentrations, the PS particles would be synthesized by following a micellar nucleation mechanism. However, the slope (0.23) of the log Np versus log Cs plot (Np: number of particles; Cs: concentration of surfactin) did not obey the Smith-Ewart theory (0.6), this probably being produced by the high adsorbability of surfactin.

LINE retrotransposition and host DNA repair machinery.

Long interspersed elements (LINEs), or non-long-terminal repeat (LTR) retrotransposons, are mobile genetic elements that exist in the genomic DNA of most eukaryotes, comprising a considerable portion of the host chromosomes. LINEs constitute endogenous mutagens that cause insertional mutations in host chromosomes and have a large impact on host genome evolution. Despite their importance, however, the molecular mechanism of LINE retrotransposition is not fully understood. Several studies suggest that host proteins that participate in the repair of DNA breaks modulate LINE retrotransposition. Recently, we provided evidence that there are 2 distinct pathways-annealing and direct-that join the 5'-end of LINEs to host chromosomal DNA. These pathways appear to be used distinctively by zebrafish LINEs and the human L1 in DT40 cells. In HeLa cells, only the annealing pathway appears to be used. This implies that different characteristics of the 2 LINEs and also host factors dictate which pathway is selected. Here, we discuss the 5'-end-joining pathways of LINE retrotransposition and propose that the pathways of LINE integration adopt certain host repair factors.

Integrated mechanism for the generation of the 5' junctions of LINE inserts.

To elucidate the molecular mechanism of the integration of long interspersed elements (LINEs), we characterized the 5' ends of more than 200 LINE de novo retrotransposition events into chicken DT40 or human HeLa cells. Human L1 inserts produced 15-bp target-site duplications (TSDs) and zebrafish ZfL2-1 inserts produced 5-bp TSDs in DT40 cells, suggesting that TSD length depends on the LINE species. Further analysis of 5' junctions revealed that the 5'-end-joining pathways of LINEs can be divided into two fundamental types-annealing or direct. We also found that the generation of 5' inversions depends on host and LINE species. These results led us to propose a new model for 5'-end joining, the type of which is determined by the extent of exposure of 3' overhangs generated after the second-strand cleavage and by the involvement of host factors.

A new mechanism to ensure integration during LINE retrotransposition: a suggestion from analyses of the 5' extra nucleotides.

Long interspersed elements (LINEs) are transposable elements that exist in the chromosomal DNA of most eukaryotes; as such, they have a large impact on the genome evolution of their hosts. LINEs mobilize by a mechanism called retrotransposition in which the LINE RNA is reverse-transcribed into DNA and then integrated into the host chromosome. The integration of the 3' end of the LINE element simultaneously occurs with the initiation of reverse transcription; this process is called target-primed reverse transcription and is one of the important characteristics of LINEs. However, the molecular mechanism of the integration of the 5' end is not well understood. Here, we show that, in cultured cells, the integrants of the zebrafish ZfL2-2 LINE produce extra nucleotides at their 5' ends, and the extra nucleotides originate from their flanking sequences. We also found that, in cultured cells, some integrants of the human L1 LINE and, in their native hosts, some endogenous elements of two other LINEs also contain 5' extra nucleotides of similar origin, suggesting that the mechanism for generation of the 5' extra nucleotides is universal among various LINEs. From these data, we propose a general mechanism for 5' integration in LINE retrotransposition.

Genetic evidence that the non-homologous end-joining repair pathway is involved in LINE retrotransposition.

Long interspersed elements (LINEs) are transposable elements that proliferate within eukaryotic genomes, having a large impact on eukaryotic genome evolution. LINEs mobilize via a process called retrotransposition. Although the role of the LINE-encoded protein(s) in retrotransposition has been extensively investigated, the participation of host-encoded factors in retrotransposition remains unclear. To address this issue, we examined retrotransposition frequencies of two structurally different LINEs--zebrafish ZfL2-2 and human L1--in knockout chicken DT40 cell lines deficient in genes involved in the non-homologous end-joining (NHEJ) repair of DNA and in human HeLa cells treated with a drug that inhibits NHEJ. Deficiencies of NHEJ proteins decreased retrotransposition frequencies of both LINEs in these cells, suggesting that NHEJ is involved in LINE retrotransposition. More precise characterization of ZfL2-2 insertions in DT40 cells permitted us to consider the possibility of dual roles for NHEJ in LINE retrotransposition, namely to ensure efficient integration of LINEs and to restrict their full-length formation.