Norman B. Hecht

Haploinsufficiency of protamine-1 or -2 causes infertility in mice

Protamines are the major DNA-binding proteins in the nucleus of sperm in most vertebrates and package the DNA in a volume less than 5% of a somatic cell nucleus. Many mammals have one protamine, but a few species, including humans and mice, have two. Here we use gene targeting to determine if the second protamine provides redundancy to an essential process, or if both protamines are necessary. We disrupted the coding sequence of one allele of either Prm1 or Prm2 in embryonic stem (ES) cells derived from 129-strain mice, and injected them into blastocysts from C57BL/6-strain mice. Male chimeras produced 129-genotype sperm with disrupted Prm1 or Prm2 alleles, but failed to sire offspring carrying the 129 genome. We also found that a decrease in the amount of either protamine disrupts nuclear formation, processing of protamine-2 and normal sperm function. Our studies show that both protamines are essential and that haploinsufficiency caused by a mutation in one allele of Prm1 or Prm2 prevents genetic transmission of both mutant and wild-type alleles.

TRANSLATIONAL REGULATION AND DEADENYLATION OF A PROTAMINE MRNA DURING SPERMIOGENESIS IN THE MOUSE

The distribution of the mRNA for one of the two mouse protamines, the cysteine-rich, tyrosine-containing protamine (MP1), was examined in the polysomal and nonpolysomal compartments of total testis and purified populations of round and elongating spermatids using Northern blots. In postmitochondrial supernatants prepared from total testis, about 10-15% of MP1-mRNA sediments with the small polysomes. The nonpolysomal molecules of MP1-mRNA are homogeneous in size, about 580 bases, while the polysomal molecules are heterogeneous with a mode of about 450 bases. Digestion with RNase H and thermal chromatography on poly(U) Sepharose reveals that the difference in size of polysomal and nonpolysomal MP1-mRNA is due to a shortening of the poly(A) from about 160 to 30 bases. In round spermatids, essentially all of MP1-mRNA is 580 bases long and is in the nonpolysomal fraction. Elongating spermatids contain roughly equal proportions of the homogeneous, 580 base form in the nonpolysomal compartment, and the heterogeneous 450 base form solely in the polysomal compartment. These results indicate that mRNA for one of the mouse protamines is stored as an untranslated RNP in round spermatids, and that it is partially deadenylated when it is translated in elongating spermatids.

Protamine 2 Deficiency Leads to Sperm DNA Damage and Embryo Death in Mice

Abstract Cytokinesis is incomplete in spermatogenic cells, and the descendants of each stem cell form a clonal syncytium. As a result, a heterozygous mutation in a gene expressed postmeiotically affects all of the haploid spermatids within a syncytium. Previously, we have found that disruption of one copy of the gene for either protamine 1 (PRM1) or protamine 2 (PRM2) in the mouse results in a reduction in the amount of the respective protein, abnormal processing of PRM2, and inability of male chimeras to transmit either the mutant or wild-type allele derived from the 129-genotype embryonic stem cells to the next generation. Although it is believed that protamines are essential for compaction of the sperm nucleus and to protect the DNA from damage, this has not been proven experimentally. To test the hypothesis that failure of chimeras to transmit the 129 genotype to offspring was due to alterations in the organization and integrity of sperm DNA, we used the single-cell DNA electrophoresis (comet) assay, ultrastructural analysis, and the intracytoplasmic sperm injection (ICSI) procedure. Comet assay demonstrated a direct correlation between the fraction of sperm with haploinsufficiency of PRM2 and the frequency of sperm with damaged DNA. Ultrastructural analysis revealed reduced compaction of the chromatin. ICSI with PRM2-deficient sperm resulted in activation of most metaphase II-arrested mouse eggs, but few were able to develop to the blastocyst stage. These findings suggest that development fails because of damage to paternal DNA and that PRM2 is crucial for maintaining the integrity of sperm chromatin.

MicroRNA Mirn122a Reduces Expression of the Posttranscriptionally Regulated Germ Cell Transition Protein 2 (Tnp2) Messenger RNA (mRNA) by mRNA Cleavage

Abstract MicroRNAs play important roles in regulating development at both transcriptional and posttranscriptional levels. Here, we report 29 microRNAs from mouse testis that are differentially expressed as the prepubertal testis differentiates to the adult testis. Using computational analyses to identify potential microRNA target mRNAs, we identify several possible male germ cell target mRNAs. One highly conserved sequence in the 3′-untranslated region (UTR) of transition protein 2 (Tnp2) mRNA, a testis-specific and posttranscriptionally regulated mRNA in postmeiotic germ cells, is complementary to Mirn122a. Mirn122a is enriched in late-stage male germ cells and is predominantly on polysomes. Mirn122a, but not another noncomplementary microRNA, inhibits the activity of a luciferase reporter construct containing the 3′-UTR of Tnp2. Site-directed mutations of Mirn122a indicate that base pairing of the 5′-region of Mirn122a to its complementary site in the 3′-UTR of Tnp2 mRNA is essential for the downregulation of luciferase activity. Real-time reverse transcription-polymerase chain reaction and ribonuclease protection assays reveal that the Mirn122a-directed decrease of the Tnp2 reporter gene activity results from mRNA cleavage. We propose that specific microRNAs, such as Mirn122a, could be involved in the posttranscriptional regulation of mRNAs such as Tnp2 in the mammalian testis.

Mouse protamine 2 is synthesized as a precursor whereas mouse protamine 1 is not.

The nuclei of mouse spermatozoa contain two protamine variants, mouse protamine 1 (mP1) and mouse protamine 2 (mP2). The amino acid sequence predicted from mP1 cDNAs demonstrates that mP1 is a 50-amino-acid protein with strong homology to other mammalian P1 protamines. Nucleotide sequence analysis of independently isolated, overlapping cDNA clones indicated that mP2 is initially synthesized as a precursor protein which is subsequently processed into the spermatozoan form of mP2. The existence of the mP2 precursor was confirmed by amino acid composition and sequence analysis of the largest of a set of four basic proteins isolated from late-step spermatids whose synthesis is coincident with that of mP1. The sequence of the first 10 amino acids of this protein, mP2 precursor 1, exactly matches that predicted from the nucleotide sequence of cDNA and genomic mP2 clones. The amino acid composition of isolated mP2 precursor 1 very closely matches that predicted from the mP2 cDNA nucleotide sequence. Sequence analysis of the amino terminus of isolated mature mP2 identified the final processing point within the mP2 precursor. These studies demonstrated that mP2 is synthesized as a precursor containing 106 amino acids which is processed into the mature, 63-amino-acid form found in spermatozoa.

cDNA clones encoding cytoplasmic poly(A)+ RNAs which first appear at detectable levels in haploid phases of spermatogenesis in the mouse

We have isolated several cDNA clones encoding cytoplasmic poly(A)+ RNAs which are enriched in postmeiotic (haploid) spermatogenic cells in the mouse. Seventeen of 750 clones from a testis cDNA library hybridized more strongly to 32P-labeled cDNA copied from cytoplasmic poly(A) RNA of round spermatids than pachytene spermatocytes. Northern gel blots demonstrated that these 17 plasmids hybridized to RNA(s) approximately 0.5 kb (1 clone), 0.7 kb (13 clones), 0.8 kb (1 clone), and 0.9 kb (2 clones). Four plasmids hybridizing to RNAs 0.7 and 0.9 kb were further characterized by Northern blots. The levels of hybridization were about 10-fold greater with RNA from round spermatids, elongating spermatids and residual bodies than from pachytene spermatocytes from adult testis. These plasmids did not hybridize with cytoplasmic poly(A)+ RNA from sexually immature testis, adult liver, or brain, larger precursors in adult testis nuclear RNA, total RNA from cultured Sertoli cells, poly(A)- RNA from adult testis or the mouse mitochondrial genome. These results demonstrate that certain poly(A)+ RNAs are abundant in haploid cells but barely or not detectable in meiotic cells suggesting the accumulation of these RNAs in round spermatids requires transcription in haploid cells.

Expression profiling reveals meiotic male germ cell mRNAs that are translationally up- and down-regulated.

Gametes rely heavily on posttranscriptional control mechanisms to regulate their differentiation. In eggs, maternal mRNAs are stored and selectively activated during development. In the male, transcription ceases during spermiogenesis, necessitating the posttranscriptional regulation of many paternal mRNAs required for spermatozoan assembly and function. To date, most of the testicular mRNAs known to be translationally regulated are initially transcribed in postmeiotic cells. Because protein synthesis occurs on polysomes and translationally inactive mRNAs are sequestered as ribonucleoproteins (RNPs), movement of mRNAs between these fractions is indicative of translational up- and down-regulation. Here, we use microarrays to analyze mRNAs in RNPs and polysomes from testis extracts of prepuberal and adult mice to characterize the translation state of individual mRNAs as spermatogenesis proceeds. Consistent with published reports, many of the translationally delayed postmeiotic mRNAs shift from the RNPs into the polysomes, establishing the validity of this approach. In addition, we detect another 742 mouse testicular transcripts that show dramatic shifts between RNPs and polysomes. One subgroup of 35 genes containing the known, translationally delayed phosphoglycerate kinase 2 (Pgk2) is initially transcribed during meiosis and is translated in later-stage cells. Another subgroup of 82 meiotically expressed genes is translationally down-regulated late in spermatogenesis. This high-throughput approach defines the changing translation patterns of populations of genes as male germ cells differentiate and identifies groups of meiotic transcripts that are translationally up- and down-regulated.

Testis-Specific Cytochrome c-Null Mice Produce Functional Sperm but Undergo Early Testicular Atrophy

ABSTRACT Differentiating male germ cells express a testis-specific form of cytochrome c (Cyt c T) that is distinct from the cytochrome c expressed in somatic cells (Cyt c S). To examine the role of Cyt c T in germ cells, we generated mice null for Cyt c T. Homozygous Cyt c T −/− pups were statistically underrepresented (21%) but developed normally and were fertile. However, spermatozoa isolated from the cauda epididymis of Cyt c T-null animals were less effective in fertilizing oocytes in vitro and contain reduced levels of ATP compared to wild-type sperm. Sperm from Cyt c T-null mice contained a greater number of immotile spermatozoa than did samples from control mice, i.e., 53.1% ± 13.7% versus 33.2% ± 10.3% (P < 0.0001) for vas deferens sperm and 40.1% ± 9.6% versus 33.2% ± 7.5% (P = 0.0104) for epididymal sperm. Cyt c T-null mice often exhibit early atrophy of the testes after 4 months of age, losing germ cells as a result of increased apoptosis. However, no difference in the activation of caspase-3, -8, or -9 was detected between the Cyt c T −/− testes and controls. Our data indicate that the Cyt c T-null testes undergo early atrophy equivalent to that which occurs during aging as a consequence of a reduction in oxidative phosphorylation.

Maternal inheritance of the mouse mitochondrial genome is not mediated by a loss or gross alteration of the paternal mitochondrial DNA or by methylation of the oocyte mitochondrial DNA

To evaluate whether the absence or modification of paternal mitochondrial DNA or methylation of the oocyte mitochondrial DNA could be the molecular basis for maternal inheritance of mitochondria in mammals, the mitochondrial genome has been analyzed in four meiotic and postmeiotic testicular cell types, and in oocytes from the mouse. All four testicular cell types including spermatozoa contain mitochondrial DNA. Between meiosis and the end of spermatogenesis the number of mitochondrial genomes per haploid genome decreases 8- to 10-fold with spermatozoa containing approximately one copy of the mitochondrial genome per mitochondrion. Restriction enzyme digestions with six different enzymes indicate no gross differences in DNA sequence in the testicular mitochondrial DNA from meiotic cells, early haploid cells, late haploid cells, and spermatozoa. By the criterion of differential digestion with the isoschizomers, MspI and HpaII, the mitochondrial DNA is not differentially methylated during spermatogenesis. No methylation differences were detected in mitochondrial DNA from sperm and oocytes following digestion with seven methylation-sensitive restriction enzymes.

Haploid accumulation and translational control of phosphoglycerate kinase-2 messenger RNA during mouse spermatogenesis

The intracellular location of the mRNA for the testis-specific isozyme of phosphoglycerate kinase-2 (PGK-2) has been determined for two spermatogenic cell types. The mRNA activity for PGK-2 from the polysomal and nonpolysomal fractions of pachytene primary spermatocytes or round spermatids has been assayed by cell-free translation with the polypeptide products monitored by immunoprecipitation, followed by one-dimensional or two-dimensional electrophoresis and fluorography. The results reveal that the majority of PGK-2 mRNA activity of round spermatids was present in the polysomal fraction while the relatively less abundant PGK-2 mRNA of pachytene primary spermatocytes was present in the nonpolysomal fraction. No PGK-2 mRNA activity was observed in the cytoplasmic RNA from primitive type A spermatogonia or prepubertal Sertoli cells. These data indicate that mature PGK-2 mRNA first appears in the cytoplasm of spermatogenic cells during the prophase of meiosis and increases in amount after meiosis. Although mature PGK-2 mRNA is present in meiotic cells it is not actively translated until after meiosis has been completed. Thus, mRNA accumulation and translational mechanisms are involved in the control of phosphoglycerate kinase-2 synthesis during spermatogenesis.