A spermatogenesis-related gene expression profile in human spermatozoa and its potential clinical applications

Paternal contribution: new insights and future challenges

It has been widely held that all that fathers essentially contribute to the next generation is half their genome. However, recent progress towards understanding biological processes such as sperm maturation and fertilization now indicates that the paternal contribution has been underestimated. To tackle some of the misconceptions surrounding the paternal contribution, the factors that are actually delivered by the sperm at fertilization and their potential developmental functions will be discussed using data from humans and animal models. Although still in their infancy, the practical applications of using sperm RNAs have already emerged in reproductive medicine as markers that are indicative of successful vasectomy. They are also beginning to appear in the forensic sciences and, within the next decade, might appear in the environmental sciences.

The controversy, potential and roles of spermatozoal RNA

The majority of cellular and molecular andrologists endorse the view that the sperm is a vessel for transporting the paternal genome to the waiting egg and nothing more. Any requirement for additional spermatozoal components that enter the ooplasm apart from the paternal centriole and the soluble egg-activating factor is generally dismissed. Many studies, however, have reported RNAs in ejaculate spermatozoa and we now know that mRNAs are delivered to the egg on fertilisation. The function and utility of sperm mRNA remains essentially unexplored. Here, we examine the controversy surrounding spermatozoal mRNA carriage, the evidence refuting its presence as an artefact and how spermatozoal mRNA is leading us to suspect that, quite apart from its undoubted diagnostic potential, it might have an important role in the establishment and maintenance of a viable paternal genome.

Novel development-related alternative splices in human testis identified by cDNA microarrays

Alternative splicing of premessenger RNA is an important regulatory mechanism that increases the diversity of proteins transcribed from a single gene. This is particularly important in the testis because germ cell expansion and differentiation require many cellular changes and regulatory steps. To investigate novel development-related alternative splicings in the human testis, complementary DNA microarray studies were conducted with the use of probes from human fetal testes, adult testes, and human spermatozoa. Of a total of 386 Unigene clusters found to be related to the development of the testis, 67 clusters showed a total of 74 novel alternative spliceoforms. Developmental stage-dependent expression was also performed for a novel Unigene, NYD-SP20 (Hs.351068), which had 4 possible novel spliceoforms and another Unigene, CRISP2 (cysteine-rich secretory protein 2, Hs.2042), which had 3 possible novel spliceoforms. These results indicate that alternative splicing plays an important role in the complicated processes of testis development and spermatogenesis.

RNA in human sperm

We have yet to develop a fundamental understanding of the molecular complexities of human spermatozoa. This encompasses the unique packaging and structure of the sperm genome along with their paternally derived RNAs in preparation for their delivery to the egg. The diversity of these transcripts is vast, including several anti-sense molecules resembling known regulatory micro-RNAs. The field is still grasping with its delivery to the oocyte at fertilization and possible significance. It remains tempting to analogize them to maternally-derived transcripts active in early embryo patterning. Irrespective of their role in the embryo, their use as a means to assess male factor infertility is promising.

Expression of a novel DnaJA1 alternative splicing in human testis and sperm

Using cDNA microarray hybridization from a human testicular cDNA library, one gene exhibiting threefold difference at expression level between adult and embryo human testes was named nDnaJA1 (a new alternative isoform of human DnaJA1 which was also named HDJ2/Hsdj/dj2, a human HSP40 homologue), which was believed to be involved in testis development and spermatogenesis. Multiple tissue polymerase chain reaction (PCR) results showed that nDnaJA1 expressed highly in testis and lung but low in thymus, prostate, colon and liver. The results of the other members of DnaJA1 family (GenBank accession numbers: D13388 and BC008182) showed that they were widely expressed. D13388 and BC008182 were highly expressed in sperm while nDnaJA1 was faintly expressed by reverse transcriptase PCR. Protein motif analysis of nDnaJA1 sequence revealed motifs of DnaJ. nDnaJA1 was considered as type I DnaJ like the other members of DnaJA1 family.

Cloning and expression of a novel CREB mRNA splice variant in human testis

Identification of genes specifically expressed in adult and fetal testis is important in furthering our understanding of testis development and function. In this study, a novel human transcript, designated human testis cAMP-responsive element-binding protein (htCREB), was identified by hybridization of adult and fetal human testis cDNA probes with a human cDNA microarray containing 9216 clones. The htCREB transcript (GenBank Accession no. AY347527) was expressed at 2.35-fold higher levels in adult human testes than in fetal testes. Sequence and ntBLAST analyses against the human genome database indicated that htCREB was a novel splice variant of human CREB. RT-PCR-based tissue distribution experiments demonstrated that the htCREB transcript was highly expressed in adult human testis and in healthy sperm, but not in testes from patients with Sertoli cell-only syndrome. Taken together, these results suggest that the htCREB transcript is chiefly expressed in germ cells and is most likely involved in spermatogenesis.