Isolation and characterization of a small putative zinc finger protein from cuttlefish epididymal sperm cells

MicroRNA expression in male infertility

Male infertility is a multifactorial disorder that involves different physiopathological mechanisms and multiple genes. In this sense, we analyse the role of miRNAs in this pathology. Gene expression analysis can provide relevant information to detect biomarkers, signalling pathways, pathologic mechanisms, and potential therapeutic targets for the disease. In this review, we describe four miRNA microarrays related to patients who present infertility diseases, including azoospermia, asthenozoospermia, and oligoasthenozoospermic. We selected 13 miRNAs with altered expressions in testis tissue (hsa-miR-122-5p, hsa-miR-145-5p, hsa-miR-16-5p, hsa-miR-193a-3p, hsa-miR-19a-3p, hsa-miR-23a-3p, hsa-miR-30b-5p, hsa-miR-34b-5p, hsa-miR-34c-5p, hsa-miR-374b-5p, hsa-miR-449a, hsa-miR-574-3p and hsa-miR-92a-3p), and systematically examine the mechanisms of four relevant miRNAs (hsa-miR-16-5p, hsa-miR-19a-3p, hsa-miR-92a-3p and hsa-miR-30b-5p) which we found that regulated a large number of proteins. An interaction network was generated, and its connections allowed us to identify signalling pathways and interactions between proteins associated with male infertility. In this way, we confirm that the most affected and relevant pathway is the PI3K-Akt signalling.

High rates of aneuploidy, mosaicism and abnormal morphokinetic development in cases with low sperm concentration

Purpose

The aim of our study was to evaluate the impact of severe male infertility (SMF) on the chromosomal status of embryos and any possible correlation between chromosomal status and embryo morphokinetics in younger women using data obtained from comprehensive preimplantation genetic tests.

Methods

The trial was conducted in an ART and Reproductive Genetics Centre between 2011 and 2018. A total of 326 cycles in cases with SMF where the female partner’s age was ≤ 35 years were evaluated. SMF is defined as sperm concentration below 5 mil/ml (million per milliliter) and divided into three subgroups according to sperm concentrations: 1–5 mil/ml, < 1mil/ml and testicular sperm. The control group of 190 cycles had normal sperm parameters.

Results

Significantly lower chromosomal euploidy rates were found in the testicular sperm group compared with the normal sperm controls when the female age was ≤ 35 years. In SMF, statistically significantly affected chromosomes were 2, 10, 11, 17, 21 and sex chromosomes. The mosaicism and abnormal morphokinetic development rates were higher in the SMF group than in control group, and this difference was significant when testicular sperm was used.

Conclusion

Lower euploidy rates, higher mosaicism rates and a higher incidence of abnormal morphokinetic development were observed in cases with testicular sperm with female partners ≤ 35 years compared with normal sperm controls. These findings suggest that PGT-A may be advisable in severe male infertility cases. Furthermore, the correlation between morphokinetics and chromosomal status was greatly reduced or absent in these most severe forms of male infertility, thus the need for new morphokinetic models.

Electronic supplementary material

The online version of this article (10.1007/s10815-019-01673-w) contains supplementary material, which is available to authorized users.

Misexpression of testicular microRNA in sterile Xenopus hybrids points to tetrapod-specific microRNAs associated with male fertility

Spermatogenesis is one of the most complex biological processes undergone by any organism, making it susceptible to perturbations that result in male sterility. Research has demonstrated that mutant phenotypes can be obtained from the disruption of epigenetic modifications, which are commonly microRNA guided. Employing the Xenopus system, whereby homogametic interspecies males are always sterile, thus violating Haldane's Rule, we deep-sequenced testes-specific small-RNAs to identify microRNAs most frequently misexpressed between sterile hybrids and their fertile parental taxa. Using these data, we cross-referenced our expression information with previously published mouse (Mus musculus) data and identified a subset of seven microRNAs common to both (miR-338, miR-222, miR-18, miR-30, miR-10, miR-196, and miR-365). We propose that these microRNAs are likely critical for spermatogenesis in all tetrapods, having retained testicular expression across ~350 million years of evolution (Amphibian-Mammal split). Gene targets of six of these microRNAs are known, and all the six associate with zinc and zinc finger proteins (both previously found critical in male fertility), and three with Hox genes (some of which have also previously been deemed critical for testicular development and male fertility). Expression information for these targets revealed that all those associated with zinc have previously been found to express in mammalian testes. One Hox target has known mammalian testicular expression, two have close relatives with known mammalian testicular expression, and two more are associated with proteins known to have mammalian testicular expression. In addition, miR-222 has prior association with spermatogenesis, and miR-30 has been found to be abundantly expressed in both mouse and human testes.

Transition of nuclear proteins and chromatin structure in spermiogenesis of Sepia officinalis

During spermiogenesis of Sepia officinalis histones are directly substituted by a molecule of precursor protamine, which is later transformed into the protamine through a deletion of the amino terminal end. In the present work, it is shown that the pattern of spermiogenic chromatin condensation consists of a phase of "patterning" and a phase of "condensation." In the phase of patterning, three structural remodelings are produced in the chromatin structure: [somatic-like chromatin --> 18 nm granules --> 25 nm fibers --> 44 nm fibers]. The first remodeling of the chromatin into granules of 18 nm takes place without the entrance of specific proteins in the spermiogenic nuclei. The second remodeling [granules of 18 nm --> fibers of 25 nm] is due to the entrance of the precursor protamine and its interaction with the DNA-histone complex. The third remodeling [fibers of 25 nm --> fibers of 44 nm] occurs simultaneously with the disappearance of histones from the chromatin. In the phase of condensation, the fibers of 44 nm coalesce among themselves to form progressively larger aggregates of chromatin. In this phase there are no substantial variations in the nuclear proteins, so that the condensation of the chromatin must respond to posttranscriptional changes of the precursor protamine (dephosphorylation, deletion of the amino-terminal end).

Evolution of octopod sperm I: comparison of nuclear morphogenesis in Eledone and Octopus

Morphogenesis of the Eledone cirrhosa sperm nucleus, as studied by electron microscopic techniques, is compared with that of Octopus vulgaris. Both species of cephalopods belong to the family Octopodidae. The results indicate that extensive nuclear helicoidization during E. cirrhosa spermiogenesis is brought about by modifications of the function of structural components already present in the late steps of O. vulgaris spermiogenesis. In particular, changes in the regulation of perinuclear microtubule contraction in E. cirrhosa spermatids, as well as a decrease in basicity of protamines, promote nuclear helicoidization. Disulphide bond formation between protamine molecules fixes the completely helicoidal shape of the nucleus in mature sperm of E. cirrhosa.

The impact of the source of spermatozoa used for ICSI on pronuclear morphology

BACKGROUND

The aim of this prospective study was to find out whether the source of spermatozoa used for intracytoplasmic sperm injection (ICSI) has an impact on the morphological features of pronucleate zygotes, which make up the basis of a pronuclear scoring system for the selection of the most viable embryos for transfer.

METHODS AND RESULTS

The study group consisted of 194 two pronucleate (2PN) ICSI zygotes, of which 144 originated from ejaculated (ES) and 50 from testicular spermatozoa (TS). At 18 h postinjection, 2PN zygotes were assessed for pronuclear alignment, polarity in nucleoli and cytoplasmic appearance; all of which were found to exhibit similar patterns of distribution between the ES and TS groups (P = not significant). At 25 h, the presence of first cleavage was similar for both groups; 11% of zygotes in the ES and 10% of those in the TS group underwent early cleavage (P = not significant). At 48 h, a quality score was obtained for cleaving embryos by multiplying the number of blastomeres with the grade of the embryo. Pronuclear scoring in both groups of spermatozoa correlated with embryo quality score at 48 h postinjection. There was a trend for a higher incidence of early cleavage and a lower incidence of pronuclear arrest with better pronuclear scoring embryos for both types of spermatozoa.

CONCLUSION

The morphological features of pronucleate zygotes at 18 h after microinjection with ES and TS are similar to each other.

Squid spermiogenesis: molecular characterization of testis-specific pro-protamines

Cuttlefish spermiogenesis is characterized by a two-step nuclear protein transition: histones-->spermatid-specific protein (protein T)-->sperm protamine (protein Sp). A similar situation can be observed in another Cephalopod species, the squid Loligo pealeii. The protein T from Loligo consists of two structural variants, T1 and T2 (molecular masses: 10788 and 10791 Da respectively), phosphorylated to different degrees (2-6 phosphate groups). The primary structures of these two variants and of the protamine variant Sp2 were established from sequence analysis and mass spectrometric data of the proteins and their fragments. T1 and T2 are closely related proteins of 79 residues. The complete structural identity of the C-terminal domain (residues 22-79) of protein T2 with the sperm protamine Sp2 (molecular mass 8562 Da, 58 residues) strongly suggests that the testis-specific protein T2 is indeed the precursor of the protamine. The transition between the precursor protein T and protein Sp results from a hydrolytic cleavage similar to that found in many proteins that are synthesized as precursors. The processing mechanism involves the specific cleavage of a Gly-Arg bond in the sequence Met/Leu18-Lys-Gly-Gly-Arg-Arg23. Furthermore, the study provides molecular evidence on the taxonomic relationship between Loligo and Sepia.